JP2019040307A - Administrative system, information processing equipment and image formation device - Google Patents

Abstract

To provide an administrative system, information processing equipment, and an image formation device that can reduce influence of status of information processing equipment controlling a device to be administrated on the administration.SOLUTION: If an A company owning an image formation device 2A concludes a support contract with a C company that is a maintenance company, and a B company owning an image formation device 2B does not conclude a support contract with the C company, at a notification timing occurred, the image formation device 2B inquiries an information processing equipment 1A (S61), then the information processing equipment 1A in a high load state instructs the image formation device 2B of deletion of data (S62), and does not permit data transmission at this notification timing. When the image formation device 2A to be supported inquiries the information processing equipment 1A (S63), the information processing equipment 1A instructs transmission of all data collected by the image formation device (S64), then the image formation device 2A transmits all data collected to the information processing equipment 1A (S65).SELECTED DRAWING: Figure 11

Description

  The present invention relates to a management system, an information processing apparatus, and an image forming apparatus.

  For example, in Patent Document 1, when notifying the information collection server of the first maintenance information that is information indicating the status of the image forming apparatus and the second maintenance information that is counter information including the number of output planes, An information processing apparatus is disclosed that performs notification of first maintenance information collected at a plurality of timings and partial second maintenance information collected at a plurality of timings in response to recovery from a communication failure.

JP 2006-50465 A

  An object of the present invention is to provide a management system, an information processing apparatus, and an image forming apparatus that can reduce the influence of the state of the information processing apparatus that manages the managed apparatus on the management.

The invention according to claim 1 includes an image forming apparatus and an information processing apparatus that manages the image forming apparatus based on data transmitted from the image forming apparatus, and the information processing apparatus includes the image forming apparatus. Management comprising: acquisition means for acquiring management information of the apparatus; and instruction means for instructing the image forming apparatus to transmit according to the management information acquired by the acquisition means and its own load state System.
According to a second aspect of the present invention, the information processing apparatus further includes a holding unit that holds a program executed by the image forming apparatus on the content of the instruction regarding the transmission of the instruction unit. 1. The management system according to 1.
According to a third aspect of the present invention, the holding means holds at least a first program and a second program that are transmitted when the load state of the device is predetermined, and the first program is a first program. The management system according to claim 2, wherein the management system is transmitted in the case of 1, and the second program is transmitted in a second case different from the first case.
The invention according to claim 4 is the management system according to claim 1, wherein the image forming apparatus executes contents different from the instruction regarding the transmission according to the load state of the image forming apparatus. .
The invention described in claim 5 is characterized in that the different contents executed by the image forming apparatus are executed based on a data type corresponding to the instruction related to the transmission. It is a management system described in 1.
According to a sixth aspect of the present invention, there is provided an acquisition unit that acquires management information of an image forming apparatus that is a management target, and the management information acquired by the acquisition unit and the load state of the image forming apparatus. In response, the information processing apparatus includes an instruction unit that issues an instruction regarding transmission.
According to a seventh aspect of the present invention, there is provided an accepting unit that accepts an instruction related to transmission from an information processing device that manages itself, and the information processing device accepts an instruction related to the transmission according to the instruction related to the transmission accepted by the accepting unit. And an image forming apparatus.

According to the first aspect, it is possible to reduce the influence of the state of the information processing apparatus on the management of the managed apparatus as compared with the case where no instruction means is provided.
According to the second aspect, it is possible to promptly instruct the managed device as compared with the case where the holding means is not provided.
According to the third aspect, in the case where the holding means is provided, it is possible to promptly give instructions according to the management information of the managed device and the load state of the information processing device.
According to claim 4, compared to the case of claim 1, it is possible to perform transmission reflecting the state of the information processing apparatus.
According to the fifth aspect, compared to the case of the fourth aspect, it is possible to perform transmission according to the type of data.
According to the sixth aspect, it is possible to reduce the influence of its own state on the management of the managed device managed by itself compared with the case where the instruction means is not provided.
According to the seventh aspect, it is possible to reduce the influence of the state of the information processing apparatus on its own management by the information processing apparatus as compared with the case where no instruction means is provided.

It is a figure which shows an example of a structure of the management system of this Embodiment. It is a block diagram of a server. It is a block diagram of a server. It is a block diagram of a program storage device. 1 is a block diagram of an image forming apparatus. It is a flowchart explaining the sequence which acquires a basic operation program. It is a flowchart explaining the sequence at the time of operation | movement. It is a sequence diagram explaining the 1st example of operation of a management system, (a) shows the case at the time of high load when (a) is a management server at normal time. It is a sequence diagram explaining the 2nd example of operation of a management system, (a) shows the case at the time of high load when (a) is a management server at the time of normal. It is a sequence diagram explaining the 3rd example of operation of a management system, (a) shows the case where a management server is normal, and (b) shows the case of high load. It is a flowchart explaining the process sequence which concerns on 1st Embodiment. It is a flowchart explaining the process sequence which concerns on 2nd Embodiment. It is a flowchart explaining the process sequence which concerns on 3rd Embodiment.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is a diagram illustrating an example of the configuration of the management system KS of the present embodiment.
As shown in the figure, the management system KS is configured by connecting a management server 1A, an analysis server 1B, a program storage device 1C, and image forming apparatuses 2A and 2B to a network NW. The management server 1A is a server that performs management services, and the analysis server 1B is a server that performs analysis services.
In this document, the management server 1A and the analysis server 1B may be referred to as a server 1, and the image forming apparatuses 2A and 2B may be referred to as an image forming apparatus 2. The management server 1A is an example of an information processing device.

  The management server 1A and the analysis server 1B are devices that perform predetermined information processing based on information from the image forming apparatuses 2A and 2B and output processing results. For example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a display device such as a display, an input device for performing input to the computer body, and the like. As the management server 1A and the analysis server 1B, for example, a personal computer, a workstation, or another computer is used. The management server 1A manages the image forming apparatuses 2A and 2B, and the analysis server 1B generates a program for the image forming apparatuses 2A and 2B by data analysis. The management server 1A and the analysis server 1B may be physically one computer, or may be realized by distributed processing using a plurality of computers.

The program storage device 1C stores the program generated by the analysis server 1B, and transmits the program to the management server 1A in response to a request from the management server 1A. The program storage device 1C includes a hard disk drive (HDD) that stores a program as a storage medium, a non-volatile memory (NVM (Non Volatile Memory)), and the like. The program storage device 1C is an example of a holding unit. It is also conceivable that the program storage device 1C is constituted by a storage device of the analysis server 1B that generates a program.
The program stored in the program storage device 1 </ b> C is a communication control program that controls what data and what form of data collected by the image forming apparatus 2 is sent, and does not include a basic operation program described later. .

The image forming apparatus 2 is an apparatus that prints an image on a medium and outputs it as a print document. The image forming apparatus 2 is a so-called “multifunction machine” having basic functions such as a printer function, a copy function, a scanner function, and a communication function.
As an image forming method in the image forming apparatus 2, for example, an electrophotographic method may be used, but other methods may be used.

Next, functions provided in the management server 1A, the analysis server 1B, the program storage device 1C, and the image forming apparatuses 2A and 2B will be described.
2 is a block diagram of the management server 1A, FIG. 3 is a block diagram of the analysis server 1B, and FIG. 4 is a block diagram of the program storage device 1C.
As shown in FIG. 2, the management server 1A includes a receiving unit 11 that receives data from the image forming apparatuses 2A and 2B, and a management information acquisition unit that acquires management information of the image forming apparatuses 2A and 2B via the network NW. 12.
The management information here refers to various data sent from the image forming apparatuses 2A and 2B, and includes information on analysis results from the analysis server 1B. Note that the management information may include information for specifying whether or not the image forming apparatuses 2A and 2B are managed by a contract and information for specifying the contract contents. In the present embodiment, since the management contract is concluded for the image forming apparatus 2A and no management contract is concluded for the image forming apparatus 2B, the management information in this case includes the image forming apparatus 2A. Information for specifying that the image forming apparatus 2B is a management target and not the management target is included. The management information acquisition unit 12 is an example of an acquisition unit.

In addition, the management server 1A includes a load detection unit 13 that detects its own load state, and a program acquisition unit 14 that acquires a program by making a program transmission request to the program storage device 1C. .
The load state mentioned here refers to the load on the CPU due to the processing in the management server 1A, and does not include the load on the storage device. Further, it is not limited to either a normal operation state or a high load state, and is determined at any one of a plurality of stages depending on the degree of load. Moreover, you may include communication load in the load state here. More specifically, a state where a failure has occurred in the management server 1A is a state where the original processing performance cannot be exhibited, and it can be said that the load is also high in this case.
In addition, the management server 1A includes a transmission unit 15 that transmits a program or the like to the image forming apparatuses 2A and 2B. The transmission unit 15 is an example of an instruction unit.

Further, as shown in FIG. 3, the analysis server 1B analyzes the data received by the data receiving unit 21 and the data receiving unit 21 as a transfer destination of the data received and transferred by the receiving unit 11 of the management server 1A. And a data analyzing unit 22 for performing the processing. Further, the analysis server 1B includes a program generation unit 23 that generates a program according to the analysis result by the data analysis unit 22, and a program transmission unit 24 that transmits the program generated by the program generation unit 23.
Such a program includes a program generated according to the analysis result and a program generated in advance and stored in the program storage device 1C. That is, the timing at which the program is generated and the timing at which the program is transmitted may be at the same time or different times. Then, according to the analysis result, the program stored in the program storage device 1C is read and transmitted to the image forming apparatuses 2A and 2B.

As shown in FIG. 4, the program storage device 1C includes a reception unit 31 that receives a program from the program transmission unit 24 of the analysis server 1B, a program storage unit 32 that stores the received program, and a management server 1A. A program transmission unit 33 for transmitting the program stored in the program storage unit 32 in response to a request. The program storage unit 32 stores various programs to be transmitted to the image forming apparatuses 2A and 2B, and a program selected by the management server 1A from the various programs is transmitted to the image forming apparatuses 2A and 2B. Thus, control may be adopted in which data transmission is executed in accordance with an instruction from the management server 1A in the image forming apparatuses 2A and 2B. Examples of the various programs mentioned here include a program that executes transmission of compressed data (an example of a first program), a program that executes transmission at different transmission times (an example of a second program), and the like. The details will be described later.
In the present embodiment, a configuration in which the program storage device 1C is provided separately from the management server 1A and the analysis server 1B is adopted. However, the present invention is not limited to this, and the management server 1A and the analysis server 1B have the functions of the program storage device 1C. An example is also possible.

FIG. 5 is a block diagram of the image forming apparatuses 2A and 2B.
As shown in the figure, the image forming apparatuses 2A and 2B receive the inquiry unit 41 that inquires the management server 1A about the load states of the management server 1A and the analysis server 1B, and various types of information received from the management server 1A. Part 42. The receiving unit 42 is an example of a receiving unit.
The load state referred to here includes not only the case where the degree of load applied to the CPU by the processing in the image forming apparatuses 2A and 2B is shown, but also the state where a failure has occurred in the image forming apparatuses 2A and 2B.

  The image forming apparatuses 2 </ b> A and 2 </ b> B also execute the acquired program to collect management information 43, a load detection unit 44 that detects its own load state, and a detection result by the load detection unit 44. And a process selection unit 45 that selects a process according to the process. The selection by the process selection unit 45 is selected by an instruction from the management server 1A, but is not limited to this, and there may be other processes.

  In addition, the image forming apparatuses 2A and 2B include a data transmission unit 46 that transmits data as an execution result by the management information collection unit 43 to the management server 1A. The data transmitted by the data transmission unit 46 is used for management of the image forming apparatuses 2A and 2B, and includes, for example, data of sensors included in the image forming apparatuses 2A and 2B, and data such as operation information and failure information. It is. The data transmission unit 46 is an example of a transmission unit.

Next, the basic operation will be described.
FIG. 6 is a sequence diagram for explaining the sequence for acquiring the basic operation program, and shows the operation for acquiring the basic operation program.
The operation shown in the figure is performed when the image forming apparatus 2 is activated, at a timing of about once a day, or at a fixed time. The image forming apparatuses 2A and 2B perform basic operations via the management server 1A. Get the program (basic program). The acquired basic operation program is a data notification rule program and is installed in the image forming apparatuses 2A and 2B.
This will be specifically described. As shown in FIG. 6, when the management server 1A requests a basic operation program from the program storage device 1C through the transmission unit 15 (see FIG. 2) (S11), the program storage device 1C receives it from the reception unit 31 ( The basic operation program received by the program storage unit 32 (see FIG. 4) is read out and transmitted to the management server 1A by the program transmission unit 33 (see FIG. 4) (S12). And management server 1A acquires a basic operation program by program acquisition part 14 (refer to Drawing 2), and registers it. Such a sequence between the management server 1A and the program storage device 1C is performed irrespective of the inquiry from the image forming apparatuses 2A and 2B.

The image forming apparatuses 2A and 2B make an inquiry to the management server 1A by the inquiry unit 41 (see FIG. 5) (S13). Such inquiries are periodically made (polling) in a predetermined order.
The management server 1A that has received the inquiry from the image forming apparatuses 2A and 2B transmits the registered basic operation program to the image forming apparatuses 2A and 2B from the transmission unit 15 (see FIG. 2) (S14). The image forming apparatuses 2A and 2B set the control program received by the receiving unit 42 (see FIG. 5) in the management information collecting unit 43 (see FIG. 5), and wait for an instruction from the management server 1A to itself. Thereafter, the operation (transmission of management information) is performed according to the basic operation program.
When the image forming apparatuses 2A and 2B are activated, a basic operation program is transmitted from the management server 1A. If the timing is once a day or a predetermined time, whether or not the basic operation program has been updated. Are updated, the updated basic operation program is transmitted to the image forming apparatuses 2A and 2B.

FIG. 7 is a sequence diagram illustrating a sequence during operation.
As shown in the figure, in the image forming apparatuses 2A and 2B, when the communication conditions according to the installed basic operation program are satisfied (S21), the inquiry server 41 changes the status of the management server 1A and the analysis server 1B to the management server. An inquiry is made to 1A (S22). The case where the communication condition is satisfied refers to a case where communication is to be performed, such as notification timing or when an event or failure occurs.

In response to this, the management server 1A transmits a data notification program (control program) to the image forming apparatuses 2A and 2B (S23). When the image forming apparatuses 2A and 2B have acquired a control program from the management server 1A in advance, or when the image forming apparatuses 2A and 2B have a rule regarding notification timing from the initial state, the management server 1A uses the data notification program. An example in which processing for returning the status of the management server 1A and the analysis server 1B is performed instead of transmission is also conceivable.
In principle, the management server 1A returns the status information of the server 1, and the image forming apparatuses 2A and 2B process with the basic operation program, but the control program for executing special control (for example, compression control or transmission timing control) is an image. You may send to forming apparatus 2A, 2B.

In the image forming apparatuses 2A and 2B, a reception program is executed (S24), data is collected and processed according to the program, and data is transmitted to the management server 1A (S25). As data processing here, the collected data may be subjected to some processing such as compression, thinning, and primary analysis, or may not be processed. That is, there are a case where data is processed and transmitted, and a case where data is transmitted without being processed. In addition to data transmission at the timing of executing the reception program, data transmission may be performed at a time later than that timing, and the data transmission time (transmission timing) is selected according to the situation. It will be.
When data is transmitted from the image forming apparatuses 2A and 2B, the management server 1A transfers the data to the analysis server 1B (S26). The analysis server 1B analyzes the transferred data (S27), and transmits an analysis result as management information to the management server 1A (S28). The analysis server 1B generates a program based on the analysis result and transmits it to the program storage device 1C instead of or in addition to transmitting the analysis result to the management server 1A.

  Here, as described above, it is assumed that the server 1 acquires management information (information on the operation and state of the image forming apparatus 2) transmitted from the image forming apparatus 2 and manages the image forming apparatus 2. . The management information is transmitted by the image forming apparatus 2 according to the basic operation program sent from the server 1 (basic transmission control). The basic operation program defines the type of information, data format, and transmission conditions (timing and data amount) for transmission of management information.

In principle, the control according to the present embodiment changes the management information transmission method according to an instruction from the server 1 in accordance with the state (load state) of the server 1. Elements that determine the “transmission method” can include the state of the server, the type of data, and the state of the image forming apparatus.
More specifically, the state of the server 1 here includes compression, change of transmission timing, and partial deletion of data in order to reduce the amount of data because the state of the server 1 is a high load state. Compression increases the compression rate so as to reduce the data size without changing the content (information amount). The change of the transmission time is to change the transmission time to be sent after 3 hours or the next day, for example, and the content (information amount) is changed although the time condition specified by the basic operation program is not satisfied. In addition, the amount of data communication is temporarily reduced. In the partial deletion of data, the amount of information is reduced by performing thinning to reduce the amount of data, and the thinning rules are predetermined for each type of data.
The transmission method is affected depending on the type of data. And the kind of data here is classified in consideration of urgency and importance. For example, the first classification should be transmitted without deletion but the transmission time should not be changed, the second classification that must be transmitted without deletion, but may be transmitted later, and a part of the data is missing. The third classification may be transmitted, but it is preferable not to change the transmission timing, and the fourth classification may be transmitted in a form in which a part of the data is missing or may be transmitted later.
On the other hand, from the viewpoint of the state on the image forming apparatus 2A side, the compression processing increases the CPU load on the image forming apparatus 2A, and the processing to be sent later holds data until transmission. The memory burden on the device 2A increases. Thus, the transmission method may be determined in consideration of the CPU load and memory load on the image forming apparatus 2A side.

Next, three modes will be described as instructions from the management server 1A. In the first aspect, when the status information (load level) of the server 1 is transmitted to the image forming apparatus 2, the image forming apparatus 2 includes a transmission method change rule according to the server status and a transmission procedure when the server 1 is changed. The management information is transmitted by the transmission method according to the basic operation program. In this aspect, priority is given to reducing the burden on the server 1, so that the burden on the image forming apparatus 2 increases.
In the second mode, when the server 1 instructs the image forming apparatus 2 to transmit, the image forming apparatus 2 transmits management information according to a transmission procedure included in the basic operation program. Since this mode selects a transmission method according to its own state, the burden on the server 1 is higher than that in the first mode.
In the third aspect, the communication control program is transmitted from the server 1, and the image forming apparatus 2 receives and installs the program, and transmits management information according to the program. In the third mode, the load on the server 1 and the communication load are high, and the load on the image forming apparatus 2 is very high. Is possible.

On the other hand, when the instruction cannot be followed due to the state (high load, failure occurrence, etc.) on the image forming apparatus 2 side, the transmission method may be changed by the initiative of the image forming apparatus 2 by a predetermined method. However, the purpose is to reduce the amount of transmission data in accordance with an instruction from the server 1. Therefore, for example, when compression is not possible due to the CPU load, the sending may be changed later or the sending may be thinned out. In addition, when it is difficult to hold data due to a memory load, it may be changed to send compressed data or send it thinned out. Furthermore, when both the CPU load and the memory load are present, for example, the sending may be changed by thinning. Note that the process of thinning data involves a slight CPU load, but the CPU load is much lighter than the compression process.
When the transmission method is changed under the initiative of the image forming apparatus 2, first, the server 1 is notified of the change of the transmission method and the changed transmission method, or an inquiry is made so that the server 1 can receive data.

Here, a principle operation example of the management system KS will be described.
FIG. 8 is a sequence diagram for explaining a first operation example of the management system KS. FIG. 8A shows a case where the management server 1A is normal (load state is normal), and FIG. 8B shows a high load state (high load state). ).
In the normal first operation example shown in FIG. 8A, when the image forming apparatus 2A makes an inquiry to the management server 1A (S31), the management server 1A is less likely to reduce the amount of data. Since it is a normal time, an instruction to transmit all data without compression is given (S32), and the image forming apparatus 2A transmits all uncompressed data to the management server 1A accordingly (S33).
In the case of high load shown in FIG. 8B, the management server 1A instructs the inquiry (S36) from the image forming apparatus 2A to transmit compressed data in order to reduce the data amount (S37). ), The image forming apparatus 2A transmits the compressed data to the management server 1A accordingly (S38).

FIG. 9 is a sequence diagram for explaining a second operation example of the management system KS. FIG. 9A shows a case where the management server 1A is normal, and FIG. 9B shows a case where the load is high.
In the second operation example at the normal time shown in FIG. 9A, when the management server 1A instructs the image forming apparatus 2A that made the inquiry (S41) to immediately transmit all data (S42), In accordance with this, the forming apparatus 2A immediately transmits all data to the management server 1A (S43).
Further, in the case of a high load shown in FIG. 9B, the management server 1A allows the transmission of data, but gives an instruction to specify the subsequent time as the transmission time (S46, S47). Data transmission from the image forming apparatus 2A is refrained. When the instructed transmission time comes (S48), the image forming apparatus 2A transmits data to the management server 1A (S49).

FIG. 10 is a sequence diagram for explaining a third operation example of the management system KS. FIG. 10A shows a case where the management server 1A is normal, and FIG. 10B shows a case where the load is high.
In the case of the third operation example in the normal state shown in FIG. 10A, the management server 1A that has received the inquiry (S51) from the image forming apparatus 2A is not in a high load state, and therefore issues an instruction to transmit all data. (S52) The image forming apparatus 2A transmits all data in accordance with this (S53).
At the time of high load shown in FIG. 10B, the management server 1A allows the image forming apparatus 2A that has made an inquiry (S56) to transmit immediately, but deletes a part of the data and stores the remaining data. A thinning transmission instruction is sent (S57). The image forming apparatus 2A performs a part of data transmission with the data thinned out in accordance with this (S58), and reduces the transmission data amount.

Next, various specific embodiments in the above-described embodiment will be described.
FIG. 11 is a sequence diagram illustrating a processing procedure according to the first embodiment.
In the first embodiment shown in the figure, the management server 1A is that of company C as a maintenance company, and the image forming apparatus 2A is that of company A that has a support contract with company C. The image forming apparatus 2B belongs to the company B that has not entered into a support contract with the company C. For this reason, the image forming apparatus 2A can receive a management service that is more prominent by the company C, while the image forming apparatus 2B cannot receive the management service as much as the image forming apparatus 2A from the company C.
The image forming apparatus 2B does not receive any management service at all, but can receive a response if there is an inquiry from the manager of the image forming apparatus 2B to the company C, for example. Therefore, it is necessary to acquire operation information, internal information, and the like of the image forming apparatus 2B.

More specifically, the management server 1A acquires management information (support target information) about the image forming apparatuses 2A and 2B in advance via the network NW. That is, the management server 1A acquires information that the image forming apparatus 2A is a management target while the image forming apparatus 2B is not a management target by the management information acquisition unit 12 (see FIG. 2).
The management information here refers to information for specifying whether or not each of the image forming apparatuses 2A and 2B connected to the management server 1A via the network NW is a management target. This is information for realizing a management service according to the content. For example, it may be information indicating the presence or absence of a maintenance contract and may include information for specifying the maintenance level.
In addition, as described above, the management service by the company C is performed using the analysis server 1B and the program storage device 1C (see FIG. 1) in addition to the management server 1A.

Here, a processing procedure when a notification timing according to the basic operation program installed in the image forming apparatuses 2A and 2B occurs when the management server 1A is in a high load state will be described.
The load state of the management server 1A itself is detected by the load detection unit 13 (see FIG. 2). More specifically, examples of the high load state of the management server 1A include a state where the remaining memory is low, a failure occurrence state, a high load state due to processing concentration after recovery, and the like.

When the image forming apparatus 2B makes an inquiry to the management server 1A at the generated notification timing (S61), the management server 1A in a high load state instructs the image forming apparatus 2B that is not a support target to delete data (S62). ). More specifically, the management server 1A acquires data collected by the image forming apparatus 2A if it is not in a high load state. However, if the management server 1A is in a high load state, the management server 1A sends an image forming apparatus to the image forming apparatus 2B. It is instructed not to transmit the 2B data at the current notification timing. In other words, the non-supported image forming apparatus 2B is not permitted to transmit data at the current notification timing.
An example is conceivable in which the management server 1A returns the state of the management server 1A, which is a high load state, to the image forming apparatus 2B, and the image forming apparatus 2B performs a process of deleting data accordingly. Further, an example is conceivable in which the management server 1A transmits a data deletion program to the image forming apparatus 2B, and the image forming apparatus 2B performs data deletion using the received program.

Further, when the management server 1A is inquired at the notification timing generated by the image forming apparatus 2A (S63), the management server 1A transmits all the data collected by the supported image forming apparatus 2A although it is still in a high load state. An instruction is given (S64). That is, in order to collect information necessary to support the image forming apparatus 2A, the management server 1A permits data transmission to the image forming apparatus 2A.
Then, the image forming apparatus 2A transmits all the collected data to the management server 1A (S65).
As described above, the management server 1A grasps its own load state, and issues an instruction regarding data transmission according to its own load state and the management information of the image forming apparatuses 2A and 2B. In addition, by adopting a configuration in which the load detection unit is provided in the analysis server 1B and the program storage device 1C, the management server 1A can determine the load states of other analysis servers 1B and program storage devices 1C in addition to its own load state. An example of grasping it and reflecting it in an instruction related to data transmission is also conceivable.

As described above, when the management server 1A side is in a high load state, the content of the transmission instruction is different from that in a state other than the high load state, and specifically, whether the management server 1A is a management target according to the management information. Is specified, and a difference is provided in the content of the instruction regarding data transmission between the management target and the non-management target. However, even if the management server 1A side is in a high load state, if there is a margin or surplus capacity, it is possible to respond as much as possible to the non-managed object after satisfying the contract contents of the managed object It is. Such management and non-management targets are realized by the management server 1A actively specifying data transmission in response to an inquiry that must be made before data transmission from the image forming apparatuses 2A and 2B. The
In other words, depending on the load state on the management server 1A side, it is possible to make no difference in the content of the transmission instruction between the image forming apparatus 2A and the image forming apparatus 2B.

FIG. 12 is a sequence diagram illustrating a processing procedure according to the second embodiment.
In the second embodiment shown in FIG. 12, the management server 1A is in a high load state, and a failure has occurred in the image forming apparatus 2A. Then, when the faulty image forming apparatus 2A makes an inquiry to the management server 1A at the notification timing (S71), the high load state management server 1A compresses and transmits the data collected by the image forming apparatus 2A. The compressed data transmission instruction (notification) is performed (S72). The management server 1A may also consider an example of transmitting a compressed data transmission instruction program to the image forming apparatus 2A among the programs generated in advance and stored in the analysis server 1B.

If it is difficult for the image forming apparatus 2A to execute a compressed data transmission instruction from the management server 1A because of a failure, the image forming apparatus 2A makes an inquiry again (S73). .
In response to this, the management server 1A issues a transmission time instruction (transmission time designation), which is an instruction about the transmission timing (S74). That is, it is an instruction not to transmit at the present time but to transmit later at a different time. As such an instruction, there may be a case where a notification timing to be generated thereafter is specified, and a case where a specific time other than the notification timing is specified.
Such an instruction to the image forming apparatus 2A is given by notification, but is not limited to this. For example, an example in which a parameter regarding a transmission timing or a program is transmitted can be considered.

When the image forming apparatus 2A has received a re-instruction for transmission time designation, but it is difficult to transmit compressed data even if the time is shifted due to a failure that has occurred in the image forming apparatus 2A, another transmission mode is determined by its own judgment. Is selected by the process selection unit 45 (see FIG. 5) and executed. That is, the image forming apparatus 2A does not always transmit data in accordance with the transmission instruction determined by the management server 1A according to the situation on the management server 1A side. Transmits data to the management server 1A in a different manner.
More specifically, since the transmission mode according to the transmission instruction from the management server 1A is difficult on the image forming apparatus 2A side, the image forming apparatus 2A does not transmit all the collected data at that time. Also, the data is not compressed and transmitted. The image forming apparatus 2A executes content different from the content of the transmission instruction from the management server 1A according to its own state. Specifically, the image forming apparatus 2A deletes data other than failure information with high priority from the collected data, and performs so-called thinned-out uncompressed data transmission that transmits the remaining high-priority data without compression. Perform (S75). The failure information referred to here is information indicating the content of a trouble that has occurred in the image forming apparatus 2A. A trouble that requires maintenance work to be performed by a maintenance worker going to the work site or such maintenance work is necessary. Contains information such as paper jams that are difficult to be made. In this example, the former is failure information with a high priority, while the latter is failure information with a low priority.
As described above, the image forming apparatus 2A not only passively transmits data in a transmission mode according to an instruction from the management server 1A side but also performs data transmission in a mode different from that, and in this sense, active. It can be said that this is data transmission in which the transmission mode is selected.

In the second embodiment, when making an inquiry to the management server 1A at the notification timing (see S71), an example in which the image forming apparatus 2A makes an inquiry by adding failure information indicating its own failure status is considered. It is done.
In the second embodiment, the stage in which the image forming apparatus 2A actively selects the data transmission mode is after the second inquiry, but is not limited to this. For example, after the first inquiry. Examples are possible.

Here, although the contents already described are included, a mode of data transmission from the image forming apparatus 2A to the management server 1A will be described.
When the image forming apparatus 2A has some kind of load including a failure, the data collected by the image forming apparatus 2A is subjected to a primary analysis depending on whether the job is in progress or the CPU load and the remaining memory capacity. In other words, the transmission timing is shifted, the compression is performed, and the data is deleted, and data transmission is performed according to the selection result to reduce the load.
For example, when the image forming apparatus 2A is performing a job such as printing, job-related information cannot be sent and the load on the CPU is high, so the transmission timing is selected. In addition, when there is a CPU load, it is difficult to perform a compression process with a load, and the transmission time is selected to be shifted. Further, when the remaining memory capacity is extremely small, it may be selected to send the result of the primary analysis without storing, select to compress, or delete and send information with low priority.
Further, when acquiring the load state of the management server 1A together with the program transmission or instead of the program transmission by an inquiry (see, for example, S22 in FIG. 7) prior to the data transmission, the image forming apparatus 2 performs data transfer according to the information. Send. For example, when the management server 1A is in a high load state, the image forming apparatus 2A selects to shift the transmission time by deferring the transmission time to the management server 1A. Further, in order not to further increase the load on the management server 1A, a selection is made to send uncompressed data without sending compressed data. When the management server 1A receives the compressed data, it may be selected to send the compressed data when the management server 1A receives the compressed data and does not immediately perform the decompression process.

Further, it is conceivable that such a data transmission mode is selected according to the type of data to be transmitted. In addition to fault information, for example, consumable information (lifetime data), various diagnostic data, operation information, job log or function-specific counter, debug log, and the like can be given as types of data. The diagnostic data here is also included in the management information described above.
For example, in the case of consumables information, there are consumables that the image forming apparatus 2 cannot operate unless the corresponding consumables are dealt with immediately, and consumables that still have time allowance. While it is necessary to transmit data to the management server 1A promptly, in the latter case, it is not always necessary to transmit data promptly, and the transmission time may be delayed. In this way, control is performed to change the data transmission mode according to the contents of the consumable information.
If it is necessary to send the message promptly, the management server 1A in a high load state gives an instruction for transmission, but the message is sent immediately in a form different from the instruction. Failure information needs to be sent early, but a part of the information to be sent when a failure occurs, for example, the fact that the failure has occurred and the type of failure that has occurred, is adopted so that the failure occurrence time is not sent. May be.

In addition to the diagnostic data of the image input device and the image output device, various diagnostic data include image quality diagnostic data and the like, and controller diagnostic data for communication and security. In addition to the power saving mode, the sleep mode, and the power on / off frequency information, the operation information referred to here includes job frequency information and the like. In addition, the debug log here is information that is collected and accumulated when a failure occurs, and the required information changes depending on the failure status. , May send part of it.
The compression algorithm may be selected depending on the type of data. The selected algorithm is notified to the management server 1A at the time of data transmission. The selection of the compression algorithm is performed, for example, under conditions such as the presence or absence of data loss, the compression rate, the compression speed, and the compression processing load. Since the compression rate depends on the data characteristics, it is conceivable to select a compression algorithm according to the data characteristics.
The instruction program from the management server 1A includes an instruction form for instructing the order of processing, rewriting of various parameters, and plug-ins, which can be selected according to the situation.

FIG. 13 is a sequence diagram illustrating a processing procedure according to the third embodiment. In FIG. 13, as in FIG. 12, the image forming apparatus 2 </ b> A to be managed and the image forming apparatus 2 </ b> B to be managed are not particularly distinguished, but as described above, it is possible to provide a difference in the content of the transmission instruction. It is.
In the third embodiment shown in FIG. 13, the CPU load of the image forming apparatus 2 is in a high load state. Then, when the image forming apparatus 2A makes an inquiry to the management server 1A at the generated notification timing (S81), the management server 1A instructs the compressed data transmission to compress and transmit the data collected by the image forming apparatus 2A. Perform (S82).

  Since the image forming apparatus 2A is in a high load state, it selects to transmit data without compression, and transmits uncompressed data (S83). More specifically, the transmission time and the amount of transmission data are selected in view of the urgency of data. That is, it is a selection between transmitting all data later or transmitting only a part of the data. Alternatively, when the urgency level of data is low, there may be a selection to delete without transmitting data.

According to the various embodiments described above, the management server 1A instructs data to be transmitted to the image forming apparatus 2A based on its own load state and management information of the image forming apparatus 2, and the image forming apparatus 2 transmits data to the management server 1A accordingly. On the other hand, the image forming apparatus 2 does not always perform data transmission according to the request of the management server 1A, but selects processing related to data transmission according to its own load state. For such data transmission, transmission timing and transmission data amount can also be selected.
As described above, the image data is transmitted from the image forming apparatus 2 to the management server 1A at the transmission timing and the transmission data amount in consideration of the load states of both the management server 1A and the image forming apparatus 2A.

  In the case of the third embodiment, unlike the case of the second embodiment, the image forming apparatus 2A does not make another inquiry to the management server 1A (see S73 in FIG. 12), and the image forming apparatus 2A itself performs the processing method. Select and respond with the selected form. When there is no need to make an inquiry to the management server 1A or when the image forming apparatus 2 cannot make an inquiry, the image forming apparatus 2 performs processing in accordance with its own rules (rules). Such an arrangement may be a case where a program acquired in advance from the management server 1A is used, or a case where the image forming apparatus 2A is provided from the initial state. In other words, when the image forming apparatus 2A itself selects another processing method, it is necessary to notify the management server 1A of the change.

  Although the present invention has been described using the embodiment, the technical scope of the present invention is not limited to the above embodiment. It will be apparent to those skilled in the art that various modifications and alternative embodiments can be made without departing from the spirit and scope of the invention.

DESCRIPTION OF SYMBOLS 1A ... Management server, 1B ... Analysis server, 1C ... Program storage apparatus, 2A, 2B ... Image forming apparatus, 12 ... Management information acquisition part, 15 ... Transmission part, 42 ... Reception part, 46 ... Data transmission part, KS ... Management system

Claims (7)

An image forming apparatus;
An information processing apparatus that manages the image forming apparatus based on data transmitted from the image forming apparatus;
Including
The information processing apparatus includes:
Obtaining means for obtaining management information of the image forming apparatus;
Instructing means for instructing the image forming apparatus to transmit according to the management information acquired by the acquiring means and its own load state;
A management system comprising:   2. The management system according to claim 1, wherein the information processing apparatus further includes a holding unit that holds a program executed by the image forming apparatus with respect to the content of the instruction by the instruction unit. The holding means holds at least a first program and a second program that are transmitted when the load state of the device is predetermined.
The management according to claim 2, wherein the first program is transmitted in a first case, and the second program is transmitted in a second case different from the first case. system.   The management system according to claim 1, wherein the image forming apparatus executes contents different from the instruction regarding the transmission according to the load state of the image forming apparatus.   The management system according to claim 4, wherein the different contents executed by the image forming apparatus are executed based on a data type corresponding to the instruction related to the transmission. Acquisition means for acquiring management information of the image forming apparatus to be managed;
Instructing means for instructing the image forming apparatus to transmit according to the management information acquired by the acquiring means and its own load state;
An information processing apparatus comprising: An accepting means for accepting an instruction related to transmission from an information processing apparatus managing itself;
Transmitting means for transmitting data for own management to the information processing apparatus in response to an instruction regarding the transmission received by the receiving means;
An image forming apparatus comprising:

Images