JP2006338270A - Ecology management system, server device and ecology management method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To properly perform resource saving of a large number of computer terminals disposed in an enterprise or the like. <P>SOLUTION: In this system having a server device (10) and client devices (20) communicably connected to each other, the client device has: a means (21) transmitting operation information showing an operation situation of the client device itself to the server device; and a means (22) controlling operation setting of the client device itself on the basis of an instruction from the server device. The server device has: a means (13) finding a workload in a prescribed period of the client device on the basis of the operation information from the client device; a means (14) deciding whether or not the workload corresponds to a fixed level previously allocated to the client device from a plurality of levels stepwise prescribed with the operation setting of the client device; a means (15) determining the operation setting of the client device on the basis of a result of the decision; and a means (16) notifying the client device of the determined operation setting. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a technology for managing a large number of computer terminals deployed in a company or the like, and more particularly to a technology for saving energy of each terminal and paper saving of printing paper.

  2. Description of the Related Art Conventionally, in view of cost reduction and environmental problems in organizations such as companies, it has been demanded to suppress power consumption of a computer terminal used in the organization and the amount of printing paper used. As a technology related to resource saving related to such a computer terminal, for example, there is one described in Patent Document 1 described later.

The technology described in Patent Document 1 is such that a communication server of an Internet service provider activates a terminal by sending a packet for requesting activation to a client terminal in an energy saving state, and notifies reception of an e-mail. It is. According to the above technique, the energy saving efficiency of the client terminal can be improved.
JP 2003-108491 A

  By the way, in the technique described in Patent Document 1, the communication server can control to activate a client terminal in an energy saving state, but in general, the setting of the terminal relating to energy saving can be arbitrarily performed by the user. Therefore, if an arbitrary setting by each user is a relatively loose setting for energy saving, there is a problem that energy costs are wasted considering that there are a large number of terminals in a company or the like.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique capable of appropriately saving resources related to a client device in a server / client type system.

  The ecology management system of the present invention includes a server device and a client device that are communicably connected to each other, and the client device transmits operation information indicating an operation status of the own device to the server device, and the server Means for controlling operation settings of the own apparatus based on an instruction from the apparatus, and the server apparatus obtains a work amount of the client apparatus for a certain period based on operation information from the client apparatus; Means for determining whether or not the workload corresponds to a predetermined level assigned in advance to the client device from a plurality of levels in which the operation settings of the device are defined in stages; and based on a result of the determination, Means for determining operation settings, and means for notifying the client apparatus of the determined operation settings

  The server device according to the present invention stipulates, in a stepwise manner, means for obtaining a work amount of the client device for a certain period based on operation information notified from the client device regarding the operation status of the client device, and operation settings of the client device. Means for determining whether or not the work amount corresponds to a predetermined level previously assigned to the client device from a plurality of levels, and means for determining an operation setting of the client device based on a result of the determination Means for notifying the client device of operation settings.

  In the ecology management method of the present invention, a client device that is communicably connected to a server device transmits operation information indicating an operation status of the own device to the server device, and the server device receives operation information from the client device. Whether or not the work amount of the client device corresponds to a predetermined level previously assigned to the client device from a plurality of levels in which the operation settings of the client device are defined in a stepwise manner. , Determining the operation setting of the client device based on the determination result, and notifying the determined operation setting to the client device.

  According to the present invention, it is possible to appropriately manage the operation settings of the client device from the server device. As a result, waste of resources in the system can be avoided without adding a management device or the like to the server / client system.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the following description, the operation mode for reducing the amount of electricity used by the computer terminal is referred to as an energy saving mode, and the operation mode for suppressing the amount of paper used in the printing process is referred to as a paper saving mode. These modes are collectively referred to as the saving mode.

  FIG. 1 shows a configuration of an embodiment of an ecology management system according to the present invention. The system 100 according to the present embodiment has a configuration in which a server device 10 including a database 11 and a management console 12 and a plurality of client devices 20 are communicably connected via a communication line 100A such as a LAN. A printing device 30 that can be used from the client device 20 is connected to the communication line 100A. When the system 100 is a corporate system, for example, the client device 20 can be regarded as a computer terminal used by an employee for business.

  The server device 10 and the client device 20 have a general hardware configuration as a computer, such as a CPU and a memory, respectively. The functional configuration described below with respect to the configuration in FIG. 1 corresponds to a program executed by each device by the CPU.

  The client device 20 includes a collection engine 21 that collects operation information indicating the operation status of the own device and transmits the operation information to the server device 10 and a setting engine 22 that controls the saving mode setting of the own device. The operation information transmitted to the server device 10 includes, for example, current consumption and voltage used per unit time, a setting state of the saving mode, the number of executed processes, a CPU usage rate, and the like. The above configuration corresponds to a program installed in the client device 20 as an agent module.

  As shown in FIG. 1, the server device 10 includes a calculation engine 13, a saving mode setting engine 14, an optimization engine 15, and a notification engine 16. These series of functional configurations correspond to a program installed in the server device 10 as a management manager.

  The calculation engine 13 obtains the work amount of the client device for a certain period based on the operation information from the client device 20. The amount of work includes the power consumption of the client device 20 and the number of printed sheets instructed by the client device 20 to the printing device 30.

  The saving mode setting engine 14 determines whether or not the work amount obtained by the calculation engine 13 corresponds to a predetermined level, which will be described later, assigned to the apparatus in advance for the operation setting of the client apparatus 20. In the server device 10, mode information that defines the operation settings of the client device 20 in a stepwise manner is stored in the database 11, and a predetermined level in this mode information is assigned to the client device 20 in advance as the above-mentioned default level. . The mode information will be described later in detail.

  The optimization engine 15 determines the operation setting of the client device 20 based on the determination result of the saving mode setting engine 14.

  The notification engine 16 notifies the client device 20 of the content determined by the optimization engine 15. This notification includes information for applying the operation setting determined by the optimization engine 15 to the client device 20 or information for prompting the user of the client device 20 to apply the operation setting. Further, the notification engine 16 notifies the management console 12 of the application result notified from the client device 20 about the new operation setting.

  FIG. 2 shows an example of mode information stored in the database 11. The illustrated example defines the energy saving mode of the client device 20. The mode information is information that divides the operating status of the client device 20 into levels and defines operation settings suitable as an energy saving mode at each level. The standby period in the illustrated operation rule refers to a period in which no input operation is performed on the client device 20 or a non-operation period of the device.

  In the example shown in FIG. 2, three levels “1” to “3” are provided. As the level value decreases, that is, as the level “3” increases to the level “1”, the power consumption of the client device 20 decreases. Represents a big situation. Therefore, the smaller the level value, the shorter the waiting period is set to shift to the suspended state.

  Note that the mode information shown in FIG. 2 is an example for explaining the present embodiment, and the content is not limited to the illustrated example, and may be set as appropriate by the system administrator. For example, instead of the transition to the suspend state in the operation regulation, the transition to the hibernation state may be performed. Further, the clock frequency may be reduced or stopped according to the number of processes obtained from the operation information or the CPU usage rate, or the disk rotation stop or supply power supply stop may be applied to the client device 20. Furthermore, instead of commonly applying the mode information as shown in FIG. 2 to all the client apparatuses 20, different settings may be performed for each apparatus or for each group.

  FIG. 3 shows an example of a predetermined level assigned in advance to the client device 20. In the illustrated example, the level “3” in FIG. 2 is assigned to the client device 20 of the client “A”, the level “1” is assigned to the client “B”, and the level “2” is assigned to the client “C”. Assigned. The assignment of the predetermined level can be appropriately set according to the machine specification of the client device 20, the assumed usage situation, and the like. For example, power consumption can be suppressed by assigning a higher level to the client device 20 intended for long-time use.

  The basic procedure of this embodiment will be described with reference to the flowchart shown in FIG. The client device 20 in the following description is assumed to be the client “A” in FIG.

  When the server device 10 receives the operation information transmitted from the client device 20 (step S1), the server device 10 supplies this to the calculation engine 13. The calculation engine 13 calculates the power consumption of the client device 20 based on the acquired operation information, and stores the calculation result in the database 11 (step S2).

  The saving mode setting engine 14 recognizes the default level of the client device 20 from the information regarding the allocation of the default level as shown in FIG. 3 (step S3), and whether the power consumption calculated earlier corresponds to this default level. It is determined whether or not (step S4). Here, the default level of the client device 20 that is the client “A” is the level “3”, and from FIG. 2, the power consumption represented by the level “3” is “less than E2 [W]”. This indicates that the normal power consumption of the client “A” is assumed to be “less than E2 [W]” on the server device 10 side.

  In such a case, if the power consumption calculated by the calculation engine 13 at the present time is “less than E2 [W]”, the power saving mode setting engine 14 determines that it corresponds to the default level. Further, when the calculated power consumption is equal to or greater than E2 [W], that is, when more power is actually consumed than expected, it is determined that the predetermined level is not supported.

  If the default level is “2” as in the case of the client “C” in FIG. 3 and the power consumption is less than E2 [W], the level “2” condition is not met. Based on the determination that the system is operating with low power consumption and energy saving, it is determined that this also corresponds to the predetermined level.

  When the power consumption corresponds to the predetermined level, it is assumed that there is no problem in the energy saving measures of the client device 20 at this time, and the operation information transmitted from the client device 20 is waited in the next cycle. If the power consumption does not correspond to the predetermined level, it is determined that the energy saving measures of the client device 20 are not appropriate, and the optimization engine 15 performs application control of the energy saving mode based on the actual level described later (step S5).

  The actual level application control will be described with reference to the flowchart shown in FIG. The actual level refers to a level corresponding to the power consumption calculated by the calculation engine 13 at the present time. Specifically, for the client device 20 whose default level is “3”, when the current power consumption is calculated as E1 [W], for example, the actual level of the client device 20 is “2” from FIG. Become. The optimization engine 15 determines an actual-level operation rule as a new operation setting of the client device 20, and performs application control of the new setting according to the following procedure.

  First, the optimization engine 15 determines whether or not the client device 20 is a target of forced application at the actual level (step S11). The forcible application is forcibly applying the actual level operation rule regardless of the status of the client device 20, and whether or not to forcibly apply is set in advance according to the management policy of the system.

  When the client device 20 is a target of compulsory application, the optimization engine 15 acquires an economic knowledge indicating the current energy saving setting from the client device 20 (step S12). In the case of the client device 20 to which the mode information of FIG. 2 is applied, the economic knowledge indicates a set value of a standby period until the transition to the suspended state. Since the setting value of the standby period in the client device 20 can be arbitrarily changed by the user, the server device 10 obtains the economic knowledge to grasp the current setting value.

  When the optimization engine 15 acquires the economic knowledge of the client device 20, the optimization engine 15 creates information instructing to change the content indicated by the economic knowledge to an actual level of operation regulation, and passes this to the notification engine 16. Specifically, for example, when “standby period: 25 minutes” is obtained as an economic knowledge from the client device 20 determined to be the actual level “2”, this is replaced with the “standby period” in accordance with the operation rule of FIG. : 15 minutes "will be instructed to change. The notification engine 16 transmits the instruction information from the optimization engine 15 to the client device 20 (step S13).

  When the client device 20 receives an instruction from the server device 10, the setting engine 22 changes the operation setting of the energy saving mode according to the instruction. As a result, the actual level is applied to the client device 20. When the client device 20 notifies the server device 10 of normal completion or abnormal end of application of the actual level, this notification is supplied from the notification engine 16 to the management console 12 (step S14). The management console 12 displays a screen about the application result in the client device 20 and notifies the management operator.

  On the other hand, when the client device 20 is not the target of forced application of the actual level (step S11: NO), the application of the actual level is determined according to the current standby period of the client device 20. The procedure will be described below.

  The optimization engine 15 obtains the standby period of the client device 20 from the operation information acquired previously (step S15). This standby period refers to a period during which the client apparatus 20 is actually in a standby state. Further, it is determined whether or not the obtained waiting period has reached the threshold of the waiting period defined by the actual level (step S16).

  Here, for example, the threshold of level “2”, that is, the threshold for shifting to the suspended state is “standby period: 15 minutes” from FIG. Therefore, in the case of the client device 20 having the level “2” as the actual level, it is determined whether or not the standby period obtained from the operation information reaches the threshold value “15 minutes”. The threshold value for the standby period is an actual level in this embodiment, but instead of this, another value prepared in advance for the determination may be used as the threshold value.

  When the waiting time of the client device 20 reaches the threshold value, the optimization engine 15 performs processing according to the above-described procedure (steps S12 to S14) in order to apply the actual level to the client device 20 (step S17: YES). Further, in consideration of the convenience of the client user, if the client side is set to determine whether or not the actual level can be applied (step S17: NO), the current energy saving measures are not appropriate for the client device 20. Along with this, a notification that the application of the actual level is recommended is sent (step S18).

  Further, when the standby period obtained from the operation information does not reach the threshold value (step S16: NO), the optimization engine 15 records a flag as a candidate for actual level forcible application (step S19). As a method of using this flag, for example, it is conceivable to forcibly apply the actual level when the flag is to be recorded again in the next cycle.

  According to the procedure described above, it is possible to manage from the server device 10 whether the energy saving measures of the client device 20 are appropriate. Thereby, waste of energy costs in the system can be avoided. Further, management can be easily performed because a management agent and an agent module are installed in the server device 10 and the client device 20 without adding a new management device or the like to the system.

  Next, the paper save mode control procedure according to the present embodiment will be described with reference to FIGS. The paper saving mode control described below may be performed in parallel with the above-described energy saving mode control or may be performed independently. When the control in both modes is performed in parallel, a print property described later may be added to the operation information transmitted from the client apparatus 20 to the server apparatus 10.

  FIG. 6 is an example of mode information held in the database 11 for the paper saving mode. In the paper saving mode of the present embodiment, as shown in FIG. 6, the level is set according to the number of printed sheets that the client apparatus 20 instructs to the printing apparatus 30 during a predetermined period such as “5 minutes”. As an example of the illustrated level, the level “1” is set for the operation state in which the number of printed sheets in “5 minutes” is “over 50 [sheets]”. At this level “1”, when the number of prints for “5 minutes” is “over 10 [sheets]”, the data for two pages is printed on the front and back of one sheet of paper instead of printing on two sheets of paper. It is stipulated that “backside printing” should be applied.

  The mode information of the paper saving mode is not limited to the illustrated example, and can be set as appropriate. For example, instead of “front and back printing”, “2 in 1”, that is, a setting for reducing and printing two pages of data on one sheet may be employed.

  The control procedure in the paper saving mode will be described with reference to the flowchart shown in FIG. When the client apparatus 20 instructs the printing apparatus 30 to perform printing within a preset period, the collection engine 21 acquires the printing property information and the number of printed sheets from the printer driver (not shown) of the client apparatus 20. This is transmitted to the server device 10 as operation information. Note that the operation information may be transmitted at regular intervals regardless of whether or not there is a print instruction within the period. If there is no print instruction within the period, this is described in the operation information.

  When the calculation engine 13 of the server device 10 obtains operation information such as print properties from the client device 20 (step S21), the calculation number 13 of the server device 10 obtains the number of prints in that period and stores it in the database 11 (step S22).

  Next, the saving mode setting engine 14 recognizes the default level assigned to the client device 20 from the information shown in FIG. 3 (step S23), and this default level corresponds to the number of printed sheets obtained by the calculation engine 13. It is determined whether or not to perform (step S24).

  Specifically, for example, it is assumed that the target client device 20 is a client “C” (FIG. 3) of a predetermined level “2”, and the number of prints for 5 minutes by this client device 20 is 60. Here, the default level “2” is based on the assumption that the operation status is “number of printed sheets: 30 [sheets] to 50 [sheets] / 5 minutes” from FIG. Therefore, the saving mode setting engine 14 determines that the operating status of the client device 20 in which the number of printed sheets for 5 minutes is 60 does not correspond to the default level. If the number of prints of the client device 20 is 50 or less, it is determined that it corresponds to the default level.

  If the number of prints of the client device 20 corresponds to the predetermined level (step S24: YES), the saving mode setting engine 14 determines that there is no problem with the paper saving measure, and the operation information transmitted from the client device 20 in the next cycle. Wait for. Further, when the number of printed sheets does not correspond to the predetermined level (step S24: NO), the optimization engine 15 performs actual level notification control on the assumption that the current paper saving measure of the client device 20 is not appropriate.

  Here, the actual level of the paper saving mode refers to the level corresponding to the operation information obtained from the client device 20, that is, the current operating status of the client device 20, as in the definition of the actual level of the energy saving mode described above. For example, when the case of the client “C” is used, since the number of printed sheets obtained by the calculation engine 13 is “60 sheets / 5 minutes”, the actual level of the client “C” is shown in FIG. 1 ".

  The optimization engine 15 determines whether or not the number of printed sheets obtained by the calculation engine 13 reaches a preset threshold value (step S25). For example, the threshold value is appropriately set in advance by an administrator or the like such as 60 sheets or more for 5 minutes for level “1” and 40 sheets or more for 5 minutes for level “2”.

  As a result of the determination, if the number of printed sheets reaches a threshold value, the optimization engine 15 acquires an economic knowledge related to print settings from the client device 20 (step S26). Then, based on the acquired eco-knowledge and the actual level operation rules, information for recommending application of the actual level to the client device 20 is created, and this is notified that the current paper saving measure is not appropriate. The information is passed to the notification engine 16 together with the information.

  As information that recommends application of the actual level, for example, the actual level of the client device 20 is level “1”, and “normal printing” that prints data for one page on one sheet is used as the economic knowledge. When it is obtained, the information is urged to add a condition of “number of printed sheets: more than 10 [sheets] / 5 minutes → backside printing” to “normal printing”.

  The notification engine 16 transmits the information received from the optimization engine 15 to the client device 20 (step S27). Further, the contents transmitted to the client device 20 are supplied to the management console 12 and notified to the management operator. Thereafter, when the client device 20 is notified of the application result related to the paper saving mode, the notification content is supplied to the management console 12.

  If the number of prints of the client device 20 does not reach the threshold (step S25: NO), a flag is recorded as a candidate to be notified of application of the actual level (step S28).

  According to the control procedure of the paper saving mode described above, it is possible to appropriately manage the paper saving measures for the printing paper from the server device 10.

  In the above procedure, even if the paper saving measures of the client device 20 are not appropriate, the application of the actual level is only recommended in consideration of the convenience of the client user. Similarly, the management format may be appropriately changed according to the management policy of the system, such as providing an option for forcibly applying the actual level.

It is a block diagram which shows the structure of embodiment of this invention. It is explanatory drawing of the mode information of the energy saving mode in embodiment. It is explanatory drawing of the example of a setting of the default level in embodiment. It is a flowchart (the 1) which shows the control procedure of the energy saving mode of embodiment. It is a flowchart (the 2) which shows the control procedure of the energy saving mode of embodiment. It is explanatory drawing of the mode information of the paper saving mode in embodiment. It is a flowchart which shows the control procedure of the paper saving mode of embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 System 100A Communication line 10 Server apparatus 11: Database, 12: Management console, 13: Calculation engine, 14: Saving mode setting engine, 15: Optimization engine, 16: Notification engine 20 Client apparatus 21: Collection engine, 22: Setting engine

Claims (22)

A server device and a client device connected to be able to communicate with each other;
The client device is
Means for transmitting operation information indicating an operation status of the own device to the server device, and means for controlling operation settings of the own device based on an instruction from the server device;
The server device
Means for obtaining a work amount of the client device for a certain period based on operation information from the client device, and a predetermined level assigned in advance to the client device from a plurality of levels in which the operation settings of the client device are defined stepwise Means for determining whether or not the workload corresponds, means for determining an operation setting of the client device based on a result of the determination, and means for notifying the client device of the determined operation setting. Characteristic ecology management system.   The ecology management system according to claim 1, wherein the server device obtains power consumption of the client device as the work amount.   The server device determines to apply an actual level corresponding to the power consumption of the plurality of levels to the operation setting of the client device when the power consumption obtained as the work amount does not correspond to the predetermined level. The ecology management system according to claim 2, wherein the client apparatus is instructed to apply the actual level.   The ecology according to claim 3, wherein the server device obtains a waiting period of the client device from the operation information, and determines the application of the actual level when the waiting period exceeds a preset threshold. Management system.   The server device obtains a standby period of the client device from the operation information when the power consumption obtained as the work amount does not correspond to the predetermined level, and when the standby period exceeds a preset threshold, The ecology management system according to claim 2, wherein an operation setting indicated by a level is notified to the client device.   The ecology management system according to claim 1, wherein the server device obtains the number of prints in a print process executed according to an instruction from the client device as the work amount.   The server device determines whether the number of printed sheets exceeds a preset threshold when the number of printed sheets calculated as the work amount does not correspond to the predetermined level, and when the number of printed sheets exceeds the threshold, the plurality of levels The ecology management system according to claim 6, wherein an operation setting indicated by an actual level corresponding to the number of printed sheets is notified to the client device. Means for determining the work amount of the client device for a certain period based on the operation information notified from the client device regarding the operation status of the client device;
Means for determining whether or not the workload corresponds to a predetermined level assigned in advance to the client device from a plurality of levels in which operation settings of the client device are defined in stages;
Means for determining an operation setting of the client device based on the result of the determination;
A server device comprising: means for notifying the determined operation setting to the client device.   The server device according to claim 8, wherein power consumption of the client device is obtained as the work amount.   When the power consumption obtained as the work amount does not correspond to the predetermined level, it is determined to apply an actual level corresponding to the power consumption among the plurality of levels to the operation setting of the client device, The server apparatus according to claim 9, wherein the client apparatus is instructed to apply the application.   11. The server apparatus according to claim 10, wherein a waiting period of the client apparatus is obtained from the operation information, and the application of the actual level is determined when the waiting period exceeds a preset threshold value.   When the power consumption obtained as the work amount does not correspond to the predetermined level, the standby period of the client device is obtained from the operation information, and when the standby period exceeds a preset threshold, the operation setting indicated by the actual level The server apparatus according to claim 9, wherein the client apparatus is notified of.   The server apparatus according to claim 8, wherein the number of prints in a print process executed according to an instruction from the client apparatus is obtained as the work amount.   When the number of printed sheets determined as the work amount does not correspond to the predetermined level, it is determined whether or not the number of printed sheets exceeds a preset threshold, and when the number of printed sheets exceeds the threshold, the printing of the plurality of levels is performed. 14. The server apparatus according to claim 13, wherein an operation setting indicated by an actual level corresponding to the number of sheets is notified to the client apparatus.   A program for causing a computer to function as the server device according to any one of claims 8 to 14. A client device that is communicably connected to the server device
Send operational information indicating the operational status of the device itself to the server device;
The server device is
Based on the operation information from the client device, the work amount of the client device for a certain period is obtained, and the work is changed from a plurality of levels in which the operation settings of the client device are defined in a stepwise manner to a predetermined level previously assigned to the client device. An ecology management method comprising: determining whether or not the amount corresponds; determining an operation setting of the client device based on a result of the determination; and notifying the determined operation setting to the client device. The server device is
The ecology management method according to claim 16, wherein power consumption of the client device is obtained as the work amount. The server device is
When the power consumption obtained as the work amount does not correspond to the predetermined level, it is determined to apply an actual level corresponding to the power consumption among the plurality of levels to the operation setting of the client device, Instructing the client device to apply
The client device is
18. The ecology management method according to claim 17, wherein operation settings of the own device are controlled based on an instruction from the server device. The server device is
19. The ecology management method according to claim 18, wherein a waiting period of the client device is obtained from the operation information, and the application of the actual level is determined when the waiting period exceeds a preset threshold value. The server device is
When the power consumption obtained as the work amount does not correspond to the predetermined level, the standby period of the client device is obtained from the operation information, and when the standby period exceeds a preset threshold, the operation setting indicated by the actual level The ecology management method according to claim 17, further comprising: notifying the client device of: The server device is
The ecology management method according to claim 16, wherein the number of prints in a print process executed in accordance with an instruction from the client device is obtained as the work amount. The server device is
When the number of printed sheets determined as the work amount does not correspond to the predetermined level, it is determined whether or not the number of printed sheets exceeds a preset threshold, and when the number of printed sheets exceeds the threshold, the printing of the plurality of levels is performed. The ecology management method according to claim 21, wherein the client apparatus is notified of an operation setting indicated by an actual level corresponding to the number of sheets.

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