KR101004761B1 - Computer power saving method - Google Patents

Abstract

A computer power saving method is disclosed. According to the present invention, a computer power saving method performed by a management server capable of network communication with a plurality of computers includes: receiving data transmitted from each computer; Determining a policy that is a criterion for determining whether the computer is in an idle state on a computer-by-computer basis or on a computer-group basis based on the received data; And transmitting the determined policy to the computer or computers belonging to the computer group.

Description

Computer power saving method

TECHNICAL FIELD The present invention relates to computers, and more particularly, to computer power management.

Power saving techniques are known to prevent unnecessary waste of computer power. Energy-saving technology puts the computer into sleep mode by determining that the user is not using the computer if there is no input for a certain period of time from the mouse or keyboard. In sleep mode, the computer receives only minimal energy. Thus, unnecessary waste of energy can be prevented while the computer is not in use.

However, there is a big problem of data loss by the existing energy saving method. This is because putting the computer into sleep mode only supplies the minimum amount of energy defined in the selected sleep mode. Therefore, if there is a document you are currently working on, it may not be saved. This is a very important problem for computer users, and their work documents can be lost due to energy savings, and can cause very large losses depending on the type of documents.

In addition, in order to effectively manage a large number of computers, organizations such as software upgrades, patches, and installations are mainly performed during times when users do not use computers. This is a big challenge for companies to adopt energy-saving technologies. In addition, computers that have been switched to energy-saving mode will not be able to access the computers from the outside through the network by default. In addition, since it takes a long time from the power saving mode to return to the normal mode according to the user's input, users are sympathetic about the effect of the energy saving option, but it is known that there are few examples.

As such, the conventional methods are unable to activate energy saving technologies effective for energy saving and carbon dioxide (CO ₂ ) due to the risk of data loss, computer management problems, user inconvenience, and inefficient energy saving.

On the other hand, a technique for saving energy even in a non-idle state of a computer by estimating the workload of the processor in the computer and dynamically controlling the processor voltage or clock is known. However, this technique measures the change in the workload at regular intervals, estimates the workload based on the measured value, and adjusts the power of the processor accordingly, so that the power consumption of the processor to estimate the workload is reduced. There is a problem that increases. In particular, the shorter the estimated time interval for a workload, the higher the power consumption of the processor.

The present invention is derived from this background, it is an object of the present invention to provide a computer power saving method for improving the existing energy saving method.

It is another object of the present invention to provide a new computer power saving method for reducing power consumption of a processor in a non-idle state.

In order to achieve the above technical problem, a method performed in a management server capable of network communication with a plurality of computers of the present invention comprises: receiving data transmitted from each computer; Determining a policy that is a criterion for determining whether the computer is in an idle state on a computer-by-computer basis or on a computer-group basis based on the received data; And transmitting the determined policy to the computer or computers belonging to the computer group.

In the policy determining step, a policy is determined by combining one or at least some of a mouse or keyboard no input time, a network traffic amount, and a CPU usage condition.

On the other hand, the method performed on each computer capable of network communication with the management server of the present invention for achieving the above technical problem, it is possible to determine a policy that is a reference for determining whether the state of the computer is in the idle state in the management server. Generating the necessary materials so that; Transmitting the generated data to the management server; Receiving a policy determined by the management server; Determining whether the computer is in an idle state based on the received policy; And if it is determined that the idle state, converting to a power saving mode.

In the switching step, the current open document is checked and the power saving mode is changed after forced storage.

Meanwhile, a method performed by a computer for power saving in a non-idle state of the present invention for achieving the above technical problem includes: accumulating and collecting processor usage data for each application; Predicting a workload distribution of a processor for each time zone based on the accumulated collected data; Determining a power schedule of a processor according to the predicted workload distribution information; And controlling at least one of a voltage and a clock of the processor for each time zone according to the determined power schedule.

The present invention provides a centralized computer power saving scheme, thereby increasing energy savings for multiple computers in the organization. In addition, the present invention can provide an optimal energy saving policy by providing an appropriate energy saving policy for each department in the organization.

In addition, the present invention, unlike the conventional simply check the input of the mouse or keyboard for the criterion for determining the idle state of the computer to determine the idle state by considering the idle state in consideration of the network traffic and CPU usage, Can be. This prevents the error of entering an energy-saving mode while an application is running or performing software upgrades, installations, and patches over the network.

In addition, the present invention prevents the loss of documents by checking and forcibly storing the open documents when switching to the power saving mode. The present invention further enhances the convenience of computer users by centrally managing the wake up of computers in the organization.

In addition, the present invention saves the power of the processor through the processor power schedule based on the processor usage information of the past, thereby preventing the processor from wasting power by performing continuous workload measurement at regular intervals. When comparing the overall processor power usage, the power schedule method according to the present invention can lower the power consumption of the processor compared to the conventional method.

The foregoing and further aspects of the present invention will become more apparent through the preferred embodiments described with reference to the accompanying drawings. Hereinafter, the present invention will be described in detail to enable those skilled in the art to easily understand and reproduce the present invention.

1 is a system configuration for computer power saving according to the present invention.

The management server 100 may perform network communication with a plurality of computers 200. Communication between the management server 100 and the computer 200 is based on TCP / IP (Transport Control Protocol / Internet Protocol) or UDP (User Datagram Protocol). An agent controller is implemented in the management server 100, and an agent managed by the agent controller is implemented in the computer 200. The agent is an application program installed in the computer 200 and plays a role of receiving data related to power saving from the agent controller 110 through networking and applying the same to the computer 200. In addition, the agent controller 110 manages various agents 210 located in the organization, and is an application program for an administrator to set various contents such as options and policies related to energy saving. The agent controller 110 may transfer policy or receive necessary data to the agent 210 through networking.

2 is an operation flowchart for computer power saving performed by the agent controller 110 implemented in the management server 100.

Agent controller 110 receives data transmitted from agents (step S210). Here, the data transmitted from the agent 210 refers to data that helps the agent controller 110 determine an appropriate policy for energy saving of the computer. According to a characteristic aspect of the invention, the material is idle time data and up time data. The idle time data has date and time information of an idle state of the computer, and the up time data has date and time information from a power-on time of the computer to a power-off time. And policy refers to baseline information that allows a computer to determine whether the current state is idle.

The agent controller 110 analyzes the received data to determine a policy for each computer or for each computer group (step S220). In detail, the agent controller 110 analyzes computer usage and power consumption using idle time data and up time data. The up time data indicates the power off time from the power on time of the computer, and the idle time data indicates how much the idle state has occurred. It's clear that you can analyze power consumption and whether users can use the computer over time and days.

The agent controller 110 determines an appropriate policy for the corresponding computer or the corresponding computer group through the analyzed computer usage and power consumption. Herein, a computer group may include various departments within an organization, for example, a material department, a management department, and a sales department. In the case of determining a policy for each computer group, a correlation analysis is performed by analyzing the results of the computers belonging to the same computer group, and the appropriate policy for the corresponding computer group is determined according to the analysis result.

According to a characteristic aspect of the present invention, the agent controller 110 determines a policy by combining any one or at least some of mouse or keyboard input time, network traffic amount, and central processing unit (CPU) usage. For example, policy decisions are made such as 10 minutes of no mouse or keyboard input, 1Kbyte per minute of network traffic, and 1% of CPU usage. In addition, even if the data analysis results sent from the agents are the same, the policy can be determined differently according to the characteristics of the group for each computer group. Furthermore, policies may be determined differently by time of day, date, holiday and season. For example, you may decide to shorten mouse or keyboard input time at night, and long daytime. The agent controller 110 transmits the policy thus determined to the computer or computers belonging to the computer group (step S230). And a confirmation message for receiving a policy from each agent is received (step S240). If the confirmation message is not received, the policy is resent to the agent.

In addition, the agent controller 110 transmits exception process information together with the policy. Exclusion process information may also be classified by computer or by computer group, which is preferably set in advance according to the characteristics of a computer user or a computer group. For example, if the computer group is a design department, the computer aided design (CAD) process will be set up as an exclusion process.

In addition, the agent controller 110 transmits wake up time information together with the policy. Wake-up time refers to time information to be converted to normal mode when the computer is in the power saving mode. Wake-up time information may also be classified by computer or by computer group. In this case, it is preferable that the administrator sets the wake-up time in advance according to the computer user personality or the computer group personality.

In addition, the agent controller 110 transmits user defined action information along with the policy. In the present specification, the user defined action refers to an action to be performed before the idle computer enters the power saving mode. The user-defined action information can also be classified by computer or by computer group, which is preferably set in advance according to the characteristics of the computer user or the computer group.

Meanwhile, in step S230, the policy transmission method is performed by any one of the following methods. First, the system administrator sends the policy directly at the present time. Second, a time schedule method of transmitting a policy corresponding to each agent at a specific time point. Third, it is an event driven method that sends the policy to the agent when a specific event such as login or logoff occurs.

3 is an operation flowchart for computer power saving performed by the agent 210 implemented in the computer 200.

Agent 210 generates the data required to determine the policy in the management server 100 (step S310). In detail, the agent 210 collects information on a power-on time and a power-off time of the computer 200 and generates uptime data based on the collected information. In one embodiment, the up time data comprises a computer identifier field, a date field, a power on time field, and a power off time field. Agent 210 also determines whether computer 200 is in an idle state and generates idle time data for the idle state. In one embodiment, the idle time data comprises a computer identifier field, a date field, an idle state start time field, and an idle state end time field.

Agent 210 transmits the generated data to the management server 100 (step S320). In one embodiment, the agent 210 generates the data at regular time intervals and transmits the data to the management server (100). In another embodiment, the agent 210 transmits the uptime data to the management server 100 immediately before the computer is powered off, and transmits the idle time data to the management server 100 at the end of the idle state.

Thereafter, the agent 210 receives a policy transmitted from the agent controller 110 described with reference to FIG. 2 (step S330). The received policy information is stored in memory. According to a characteristic aspect of the present invention, the policy provided from the agent controller 110 is configured by combining any one or at least some of a mouse or keyboard no input time, a network traffic amount, and a CPU usage condition. Preferably, the policy may be one of three things.

① No mouse or keyboard input time, network traffic

② No mouse or keyboard input time, CPU usage

③ No mouse or keyboard input time, network traffic, CPU usage

Furthermore, the policy provided from the agent controller 110 may be different for day, night, holiday, and season.

Meanwhile, the agent 210 having received the policy determines whether the computer 200 is in the idle state based on the policy (step S340). Preferably, the agent 210 determines that the computer is in an idle state only when all conditions in the policy are satisfied. For example, if the received policy is the policy ① of the three listed above, the agent 210 is not idle even if the current computer's mouse or keyboard no input time satisfies the policy ①. It is not judged. To explain more easily, when the policy ① says the policy mouse or keyboard no input time '10 minutes' and the network traffic amount 'less than 1Kbyte per minute', the input from the mouse or keyboard did not occur for 10 minutes, but the network traffic volume per minute If it is more than 1Kbyte, it is determined that it is not idle.

Unlike the conventional method of determining whether the computer is in the idle state by considering only the mouse or keyboard no input time as described above, the present invention determines whether the idle state is further considered in consideration of the amount of network traffic, CPU usage, or both. . This is to detect a more accurate idle state, and also to prevent computer errors.

In other words, for example, a rendering process of data that has been performed by a computer (Aided Design) computer without a computer may be performed. The idle state is regarded as idle, and the rendering process is ignored and the power saving mode is switched. This may cause rendering errors. However, according to the present invention, since it is determined that the CPU is not in the idle state through the CPU usage, there is no need to switch to the power saving mode, thereby preventing an error.

As another example, when the administrator performs a software upgrade, installation, or patching process for the computers 200 on the management server 100 through networking, the mouse or keyboard input may be timed by a conventional method. If not, the computer is determined to be idle and will go to sleep, bypassing the software upgrade, installation, or patching process. This can cause upgrades, installations, or patch errors. However, according to the present invention, since it is determined that the network traffic is not in the idle state, there is no need to switch to the power saving mode, thereby preventing an error.

On the other hand, if it is determined that the computer 200 is in the idle state, the agent 210 switches to the power saving mode (step S350). Preferably switch to standby mode. Using standby mode as a power saving mode saves the current usage environment in a random access memory (RAM), which allows the user to quickly switch to normal mode.

In accordance with a characteristic aspect of the present invention, the agent 210 checks whether there are currently open documents before entering the power saving mode. If there is an open document, the agent 210 executes a script engine to forcibly save the work in the document. This is one of the important reasons why users do not use the power saving mode. If you leave your desk for a while, or think about it, you can go to sleep without saving the document. Therefore, to solve this problem, the agent 210 according to the present invention solves the conventional problem by executing a script engine capable of forcibly storing a document instead of immediately switching to a power saving mode by detecting an idle state of a computer. have.

In addition, the agent 210 sets up the wake-up time by referring to the wake-up time information transmitted together with the policy from the agent controller 110 before switching to the power saving mode. The reason for setting up the wake up time is for the convenience of the computer user. For example, the computer will normally be idle during lunch, so if you set your wake up time at the end of the lunch break, you won't have to spend time switching from sleep mode to normal mode. It offers the advantage of being able to get things done right away. However, in addition to this, if the agent controller 110 of the management server 100 provides the wake-up time information to the agents 210 differently according to the characteristics of each computer or group of computers, the computer user may provide a customized wake-up service. I can receive it.

In addition, the agent 210 performs a user defined action before entering the power saving mode. This custom action information is provided from the agent controller 110. A custom action might be, for example, log off for security. For example, you can connect to the management server and check if there are any updates to the software.

Meanwhile, even if the computer is in the idle state, the agent 210 does not switch to the power saving mode if the running process belongs to the excluded process information. Specifically, the agent 210 receives the exclusion process information transmitted with the policy from the agent controller 110 and stores it in the memory. If it is determined that the computer is in the idle state, it checks the currently running process and checks whether the checked process is a process registered in the excluded process information. If registered in the excluded process information, the agent 210 does not enter the power saving mode until the execution of the process is finished. Of course, if the process is running, it will not be detected as idle due to CPU usage, but this is just to prevent the killing of the running process.

4 is an operation flowchart for computer power saving in a non-idle state performed in the agent 210 implemented in the computer 200.

In the non-idle state, the agent 210 collects data on CPU usage of the running application at regular time intervals (step S410). Specifically, data about CPU usage is collected for each task within an application. Collected data is cumulatively managed. Agent 210 assigns a weight to each of the data collected for a certain period of time (step S420). Preferably more weight is assigned to recent data. For example, if there are 10 data collected for one application, the 10th collected data is assigned a high weight of '100' and the 1st collected data is assigned a low weight of '1'.

The agent 210 predicts a workload distribution of the time-phase processor based on the cumulative collected data and weights (step S430). The power required by the processor according to the time slot is calculated according to the predicted result, and power scheduling is performed accordingly (step S440). An important point in the power schedule is to divide the processor power range into sections for scheduling and to set an appropriate section by reflecting the worker load distribution prediction result of the time zone processor. For example, the processor power range is divided into sections such as 1 to 3 volts, 2 to 4 to 6 volts, 3 to 7 to 8 volts, and 4 to 9 volts. To set. When the power schedule is determined, the agent 210 controls the power of the processor according to the power schedule (step S450). In operation S450, the agent 210 may change only the voltage, only the clock, or both of them for power control of the processor. This follows as specified in the power schedule.

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a system configuration for computer power saving according to the present invention.

2 is an operation flowchart for computer power saving performed by an agent controller implemented in a management server.

3 is an operation flowchart for computer power saving performed by an agent implemented in a computer.

4 is a flowchart of operations for computer power saving in a non-idle state performed in an agent implemented in a computer.

<Explanation of symbols for the main parts of the drawings>

100: management server 110: agent controller

200: Computer 210: Agent

Claims (20)

In the method performed in the management server capable of network communication with a plurality of computers, Receiving material transmitted from each computer; Determining a policy that is a criterion for determining whether the computer is in an idle state on a computer-by-computer basis or on a computer-group basis based on the received data; And Transmitting the determined policy to the computer or computers belonging to the computer group; Computer power saving method comprising a. The method of claim 1, The received data may include idle time data in which date and time information of an idle state is recorded, and up time data in which date and time information from a power-on time to a power-off time of a computer are recorded. A computer power saving method characterized by the above. The method of claim 2, The policy determining step may include analyzing computer usage and power consumption using the idle time data and the up time data, and determining a policy for each computer or group of computers based on the analyzed result. . The method of claim 1, The determining of the policy may include determining a policy differently in consideration of at least one of a time zone, a date, a holiday, and a season. The method of claim 2, The policy determining step includes determining a policy by combining one or at least some of a mouse or keyboard no input time, a network traffic amount, and a CPU usage condition. The method of claim 1, The transmitting step may further transmit the exclusion process information to determine whether the process running on the computer corresponds to the exclusion process for holding the transition to the sleep mode before determining whether the computer is in the idle state and entering the sleep mode. Computer power saving method characterized in that. The method of claim 1, The transmitting may further include transmitting time information to be woken up by the computer operating in the power saving mode. A method performed on each computer capable of network communication with a management server, Generating data necessary for the management server to determine a policy which is a criterion for determining whether the state of the computer is in the idle state; Transmitting the generated data to the management server; Receiving a policy determined by the management server; Determining whether the computer is in an idle state based on the received policy; And If determined to be in the idle state, switching to the power saving mode; Computer power saving method comprising a. The method of claim 8, The data generating step may include idle time data in which date and time information of an idle state is recorded, and up time data in which date and time information from a power-on time to a power-off time of a computer are recorded. A method of power saving a computer, characterized by a collection. The method of claim 8, Wherein the received policy includes one or at least some of a mouse or keyboard no input time, a network traffic amount, and a CPU usage condition. The method of claim 10, And the determining step is determined as an idle state when all the conditions of the policy are satisfied as the idle state. The method of claim 8, The switching step, the computer power saving method, characterized in that for switching to the power saving mode after forced storage by checking the currently open document. The method of claim 8, The switching step, when there is a process running in the idle state, the computer power saving method characterized in that the transition to the power saving mode only if the running process is not registered in the excluded process information provided from the management server. The method of claim 8, In the switching step, after the wake-up time is set according to the wake-up time information provided from the management server, the computer power saving method, characterized in that for switching to the power saving mode. The method of claim 8, The switching step, after the action included in the user defined action (user defined action) information provided from the management server, the computer power saving method, characterized in that for switching to the power saving mode. The method of claim 8, And the power saving mode is a standby mode. delete delete delete delete

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