KR101210854B1 - Intelligent power saving control system using patten cognition art and intelligent power saving policy establishment method in power saving control system - Google Patents

Abstract

The present invention discloses an intelligent power saving control system using a pattern recognition technology and an intelligent power saving policy setting method in the intelligent power saving control system. In one embodiment, the power saving mode control unit for switching the user PC to the standby mode or the normal mode according to the intelligent power saving policy; A pattern data collector configured to collect and provide inactive state holding time information switched by the power saving mode controller; A pattern data storage unit for storing the inactive state holding time information provided from the pattern data collecting unit for a preset period, and storing the stored inactive state holding time information by grouping the stored time periods in a specific unit of time; And a power saving mode policy setting unit that obtains a weight for each group and sets an intelligent power saving policy by adding weights to the inactive time keeping time of each specific unit, and collects and analyzes user PC usage pattern information. By automatically setting the sleep mode standby time, you can optimize the power management of your computer.

Description

Intelligent power saving control system using patten cognition art and intelligent power saving policy establishment method in power saving control system}

The present invention relates to an intelligent power saving control system using a pattern recognition technology and an intelligent power saving policy setting method in the intelligent power saving control system. The present invention relates to an intelligent power saving control system using pattern recognition technology that automatically collects, analyzes, and automatically sets an optimal power saving mode standby time, and an intelligent power saving policy setting method in the intelligent power saving control system.

Currently, the operating system of the user's PC provides a power saving mode function to save power.

As shown in FIG. 1, the power saving mode function manually sets a condition for the user to enter the power saving mode through the standby time setting unit 20 and stores the condition in the storage unit 30. If so, the operating system 40 automatically switches the state of the user's PC to the power save mode.

That is, the operating system 40 changes the state of the user PC to the power saving mode when a state in which there is no user input (hereinafter, inactive state) from the input device 10, such as a keyboard or a mouse, continues for a preset time. When the user's PC enters the power saving mode and inputs to the input device such as the keyboard or the mouse, the user PC is converted back to the normal mode.

However, if the user sets the power saving mode standby time too long, the power saving function of the conventional user's PC does not enter the power saving mode even though it is actually disabled, and the power saving function does not work properly. Too often enter the power saving mode has a problem that the user becomes uncomfortable.

The present invention is to solve the above-mentioned problems, intelligent power saving control system using a pattern recognition technology to automatically set the optimal power saving mode standby time by collecting and analyzing the user's PC usage pattern information and its intelligent power saving control system To provide an intelligent power saving policy setting method in.

In addition, to provide an intelligent power saving control system using a pattern recognition technology that can be controlled by the power management server in a centralized manner to control the on / off of a large number of user PCs and intelligent power saving policy setting method in the intelligent power saving control system There is another purpose.

One aspect of the intelligent power saving control system using the pattern recognition technology of the present invention is a power saving mode control unit for switching the user PC into the standby mode or the normal mode according to the intelligent power saving policy; A pattern data collector configured to collect and provide inactive state holding time information switched by the power saving mode controller; A pattern data storage unit for storing the inactive state holding time information provided from the pattern data collecting unit for a preset period, and storing the stored inactive state holding time information by grouping the stored time periods in a specific unit of time; And a power saving mode policy setting unit for obtaining a weight for each group divided by time zones of a specific unit, and setting an intelligent power saving policy by adding weights to each group.

The power saving mode policy setting unit obtains a value (a) obtained by squaring the number of inactive state holding times belonging to each group, obtains a sum value (b) of square values (a) of each group, and then adds up the sum value (b). The weight of each group is calculated by dividing the number of inactivity holding time of each group by the squared value (a), and the result of multiplying the weighted value of each group by the average value of the inactivity keeping time for each specific unit is added. Set the waiting time for entering the power saving mode.

Here, the power saving mode control unit and the pattern data collecting unit are installed in the user PC, and the pattern data storage unit and the power saving mode policy setting unit are installed in the power saving management server.

Another aspect of an intelligent power saving control system using a pattern recognition technology of the present invention includes a power saving management server including an on / off control signal for turning on or off a power of a user PC to an integrated gate and a corresponding user PC, respectively; An integrated gate having a wireless communication unit, converting an on / off control signal received from a power management unit of a power saving management server into a wireless signal and transmitting the wireless signal to a corresponding multi-tap; A wireless communication module that receives and provides an on / off control signal transmitted wirelessly through the wireless communication unit of the integrated gate, and controls a relay switch according to an on / off control signal provided through the wireless communication module to a user PC. A plurality of multi-taps comprising a power control module for switching the supplied power, and a relay switch switched to supply or cut off power to the user PC according to the control of the power control module; And a power control unit for controlling the user PC which is turned off when the power is supplied from the multi-tap and receiving an on / off control signal from a power saving management server, or for turning off the standby user PC. It may further include.

The user PC may further include a state information providing unit for transmitting the state information of the user PC to the power saving management server.

The integrated gate and the multi-tap perform communication by using wireless communication such as Zigbee, Bluetooth, or WLAN.

An aspect of an intelligent power saving policy setting method in an intelligent power saving control system using a pattern recognition technology of the present invention includes: collecting, by a pattern data collecting unit, inactive state holding time information switched by a power saving mode control unit to a pattern data storage unit; Storing, by the pattern data storage unit, the inactive state holding time information provided from the pattern data collecting unit for a predetermined period, and storing the stored inactive state holding time information by grouping the time slots in a specific unit of time; Calculating, by the power saving mode policy setting unit, a weight for each group; And setting, by the power saving mode policy setting unit, a power saving mode entry waiting time by multiplying an average value of the inactive state holding time of each operating time unit by a weight of each operating time unit and adding the result.

The calculating of the power saving mode policy setting unit weights for each group may include: obtaining a value (a) obtained by squaring the number of inactive state holding times belonging to each group; Obtaining a sum (b) of square values (a) of each group; And calculating a weight for each group by dividing a value (a) obtained by squaring the number of inactive state holding times of each group by the sum value (b).

With the above-described configuration, the intelligent power saving control system using the pattern recognition technology according to the present invention and the intelligent power saving policy setting method in the intelligent power saving control system collect and analyze user PC usage pattern information to automatically determine the optimal power saving mode standby time. By setting it to, it has an excellent effect to optimize the power management of the computer.

It also has another great effect of controlling the power saving function of many user PCs through the power management server.

1 is a functional block diagram showing a standby mode control system of a conventional computer.
2 is a functional block diagram showing the configuration of an intelligent power saving control system using a pattern recognition technology according to the present invention.
Figure 3 is a functional block diagram divided into a server and a client in an intelligent power saving control system using the pattern recognition technology according to FIG.
4 is an actual state diagram of an intelligent power saving control system using the pattern recognition technology of FIG. 2.
5 is a flowchart illustrating a method for setting an intelligent power saving policy in an intelligent power saving control system using a pattern recognition technology according to the present invention.
FIG. 6 is a functional block diagram illustrating a system for supporting a remote power saving function in an intelligent power saving control system using the pattern recognition technology of FIG. 2.

The following detailed description of specific embodiments provides several descriptions of specific embodiments of the present invention. However, the present invention can be implemented in many different ways, which are defined and covered by the claims. The detailed description is described with reference to the drawings, wherein like reference numerals refer to the same or functionally similar elements.

The terminology used in the detailed description provided herein is for the purpose of describing particular embodiments of the invention only and should not be construed as limiting or limiting the invention to the specific methods. Furthermore, embodiments of the present invention may include a number of novel features which are necessary to represent the overall desirable properties of the invention or to practice the invention provided herein.

2 is a functional block diagram showing the configuration of an intelligent power saving control system using a pattern recognition technology according to the present invention.

Intelligent power saving control system using a pattern recognition technology according to an embodiment of the present invention, the power saving mode control unit 110, pattern data collection unit 120, pattern data storage unit 210 and power saving mode policy setting unit 230 Include.

The power saving mode control unit 110 is an active state (mouse and keyboard inactive for a predetermined time) and an inactive state (mouse and keyboard) of an input device (not shown) of the user PC 100. Is activated, and the deactivation state of the input device is in standby mode entry waiting time according to the intelligent power saving policy including information on standby mode entry waiting time of the input device for switching the user PC 100 to the standby mode. When reaching, the user PC 100 is switched to the standby mode, and when the input device of the user PC 100 in the standby mode is activated, the user PC 100 in the standby mode is switched to the normal mode. Here, the standby mode of the user PC 100 is to turn off the screen of the monitor or to save power to the user PC main body.

The pattern data collection unit 120 collects inactive state maintenance time information of the corresponding user PC 100 and provides the pattern data storage unit 210.

The pattern data storage unit 210 stores the inactive state holding time information provided from the pattern data collection unit 120 by grouping the time zones in a specific unit. Here, the time zone of a specific unit may be 5 minutes, 10 minutes, or a time unit arbitrarily set by a user.

The power saving mode policy setting unit 230 obtains a value (a), which is the square of the number of inactive state holding times belonging to each group, obtains a sum value (b) of the square value (a) of each group, and then adds the sum value ( b), the weight of each group is calculated by dividing the value (a) of the number of times of inactivity maintaining time of each group.

The power saving mode policy setting unit 230 sets the power saving mode entry waiting time by adding the result of multiplying the weight of each group to the average value of the inactive state holding time belonging to each group divided by time zone of a specific unit.

3 is a functional block diagram of the intelligent power saving control system using the pattern recognition technology according to FIG. 2 installed in the client and the power saving management server, respectively, and FIG. 4 is a state diagram of the intelligent power saving control system using the pattern recognition technology according to FIG. 5 is a flowchart illustrating a method for setting an intelligent power saving policy in an intelligent power saving control system using a pattern recognition technology according to the present invention.

First, the power saving mode control unit 110 and the pattern data collecting unit 120 are generally installed in the user PC 100, and the pattern data storage unit 210 and the power saving mode policy setting unit 230 are the power saving management server 200. ) Can be installed.

In this case, the power saving management server 200 and the plurality of user PCs 100 are connected through the hub 201.

Here, the local operator console 300 may be connected to the power saving management server 200 to manually control the power saving control of the user PC 100, and the remote operator console 310 may be connected through the WAN 320.

As such, when the power management server 200 and the user PC 100 are connected, the power saving mode control unit 110 monitors the activation and deactivation states of the mouse and keyboard, which are input devices of the user PC 100, and monitors the intelligent power saving policy. Accordingly, when the deactivation state of the input device reaches the standby mode entry waiting time, the corresponding user PC 100 is switched to the standby mode (S1).

Subsequently, the power saving mode control unit 110 installed in the user PC 100 checks whether the input device of the corresponding user PC 100 in the standby mode is activated, and when the input device is activated, the corresponding user PC 100 in the standby mode. ) To the normal mode (S2).

At this time, the pattern data collection unit 120 installed in the user PC 100 collects inactive state maintaining time information and provides the pattern data storage unit 210 installed in the power saving management server 200 (S3).

Then, the pattern data storage unit 210 installed in the power saving management server 200 stores the inactive state holding time information provided from the pattern data collection unit 120 installed in the user PC 100 in the data storage 220.

Here, the pattern data storage unit 210 divides the deactivated state holding time information stored in the data storage 220 into groups according to time zones in a specific unit (S4). Here, the time zones to be grouped may be 5 minutes, 10 minutes or a time unit arbitrarily set by the user.

In the following, it is assumed that the inactive state holding time information (1 minute, 3 minutes, 5 minutes, and 7 minutes) has been collected from the pattern data collecting unit 120, and divided into time-based groups of 5 minutes.

Therefore, the pattern data storage unit 210 includes the inactive state holding time information (three times) of one minute, three minutes, and five minutes in a five-minute group (0 to 5 minutes), and the seven minute inactive state holding time information ( Once) is included in 10-minute group (6-10 minutes).

Thereafter, the power saving mode policy setting unit 230 calculates a weight for each group (S5).

To this end, the power saving mode policy setting unit 230 obtains a value (a) obtained by squaring the number of inactive state holding times of the 5-minute group (0-5 minutes) and the 10-minute group (6-10 minutes), respectively.

Since the 5-minute group (0-5 minutes) stores inactivity time information of 1 minute, 3 minutes, and 5 minutes, the squared value becomes "9" when the number of times of inactivity time information (3) is squared. In the 10-minute group (6 to 10 minutes), since the 7-minute deactivation holding time information is stored, the square value becomes “1” when the number of times 1 of the deactivation holding time information is squared.

Thereafter, the power saving mode policy setting unit 230 calculates the sum value (b) "10" by adding the square values (a) "9" and "1" of each group.

As described above, the weight of the 5 minute group (0 to 5 minutes) set through the power saving mode policy setting unit 230 becomes "9/10", and the weight of the 10 minute group (6 to 10 minutes) is "1 /. 10 ".

Subsequently, the power saving mode policy setting unit 230 has a weight value (9/5) of the 5-minute group (0-5 minutes) to the average value of the inactive state holding time (1 + 3 + 5/3) of the 5-minute group (0-5 minutes). 10) multiplied by the average value (7/1) of the deactivation time of the 10-minute group (6-10 minutes) and the weight (1/10) of the 10-minute group (6-10 minutes) The wait time (3.4 minutes) for entering the power saving mode is set by adding the value (0.7) (S6).

Thereafter, the power saving mode controller 110 applies the standby mode of the user PC 100 according to the set power saving mode entry waiting time (3.4 minutes).

6 is a functional block diagram for supporting a remote power saving function in an intelligent power saving control system using the pattern recognition technology of FIG. 2.

The intelligent power saving control system using the pattern recognition technology of the present invention includes a power saving management server 200 having a power management unit 240, an integrated gate 400 having a wireless communication unit 410, and a wireless communication module 510. And a plurality of multi-taps 500 including a power control module 520 and a relay switch 530, a plurality of user PCs 100 including a status information providing unit 130 and a power control unit 140. It may include.

In the above configuration, the power management unit 240 of the power saving management server 200 transmits an on / off control signal for turning on or off the power of the user PC 100 to the integration gate 400 and the user PC 100, respectively. . In this case, the information of the user PC 100 and the multi-tap 400 is matched and stored in the power saving management server 200.

The wireless communication unit 410 of the integrated gate 400 converts the on / off control signal received from the power management unit 240 of the power saving management server 200 into a wireless signal and transmits the converted signal to the corresponding multi-tap 500. At this time, the integrated gate 400 and the multi-tap 500 performs communication by using a wireless communication such as Zigbee, Bluetooth or WLAN.

The wireless communication module 510 of the multi-tap 500 receives an on / off control signal transmitted through the wireless communication unit 410 of the integrated gate 400 and provides it to the power control module 520.

The power control module 520 of the multi-tap 500 controls the relay switch 530 according to the on / off control signal provided through the wireless communication unit 410 to switch the power of the user PC 100.

In addition, the relay switch 530 of the multi tap 500 supplies power to the user PC 100 or cuts off power supply of the user PC 100 according to an on / off control signal provided through the power control module 520. Is switched to.

The power control unit 140 of the user PC 100 may turn on the power of the user PC 100 which is turned off when a control signal from the power saving management server 200 is received while power is supplied from the multi-tap 500. To control. The power control unit 140 may be a LAN card having a Wake on Lan function.

On the other hand, when the power control unit 140 of the user PC 100 receives the off control signal from the power management server 200 while the power is supplied from the multi-tap 500, the power control unit 140 turns off the user PC 100 that is in a standby state or turned on. Let's do it.

In addition, the state information providing unit 130 of the user PC 100 transmits the state information (standby mode or normal mode) of the user PC 100 to the power saving management server 200.

When the standby time of the user PC 100 exceeds the preset time, the power saving management server 200 receiving the status information from the user PC 100 transmits an off control signal to the corresponding user PC 100 to transmit the corresponding user PC ( The power of 100 may be terminated and the power of the user PC 100 may be terminated by transmitting an off control signal to the corresponding user PC 100 at a preset time.

In addition, the power saving management server 200 may supply power to the user PC 100 by transmitting control signals to the multi-tap 500 that supplies power to the corresponding user PC 100 through the integrated gate 400. Control the controller 100 to transmit the on / off control signal to the corresponding user PC 100 through the hub 201 to turn on the power of the corresponding user PC 100, and to turn on the control signal at a preset time. By transmitting, the power of the user PC 100 may be turned on.

In addition, the power management server 200 transmits an off control signal to the corresponding user PC 100 through the hub 201 to turn off the power of the corresponding user PC 100, and then, after a preset time, the integrated gate 400. By transmitting the OFF control signal to the multi-tap 500 for supplying power to the user PC 100 through the control unit can be controlled to cut off the power supplied to the user PC (100).

Although the foregoing detailed description has shown, described, and mentioned the basic novel features of the invention as applied to the various embodiments, various omissions, substitutions, and changes in the form and details of the illustrated system may be made without departing from the intention of the invention. It will be appreciated that changes may be made by those skilled in the art.

100: user PC 110: power saving mode control unit
120: pattern data collection unit 130: status information provider
140: power control unit
200: power management server 210: pattern data storage unit
230: power saving mode policy setting unit 240: power management unit
400: integrated gate 410: wireless communication unit
500: multi-tap 510: wireless communication module
520: power control module 530: relay switch

Claims (8)

A power saving mode control unit for switching the user PC into the standby mode or the normal mode according to the intelligent power saving policy;
A pattern data collection unit for collecting and providing information on an inactive state holding time of the input device;
A pattern data storage unit for storing the inactive state holding time information of the input device provided from the pattern data collecting unit and grouping the stored inactive state holding time information for each time zone in a specific unit; And
It includes a power saving mode policy setting unit for obtaining the weight for each group divided by time zone of a specific unit, and setting the intelligent power saving policy by adding weight to each group,
The power saving mode policy setting unit obtains a square value (a) of the number of inactive state holding times belonging to each group and a sum value (b) of the square value (a) and then squares the sum value with the sum value (b). By using the pattern recognition technology to calculate the weight of each group by dividing the value (a), and to add the result of multiplying the weight of each group by the average value of the inactive state maintenance time of each specific unit by using the pattern recognition technology Intelligent power saving control system.
delete The method of claim 1,
The power saving mode control unit and the pattern data collecting unit is installed in the user PC, the pattern data storage unit and the power saving mode policy setting unit is installed in the power saving management server, intelligent power saving control system using a pattern recognition technology.
A power saving management server including an on / off control signal for turning on or off a user PC to an integrated gate and a power management unit for transmitting to the user PC;
An integrated gate having a wireless communication unit, converting an on / off control signal received from a power management unit of the power saving management server into a wireless signal and wirelessly transmitting the multi-tap to a multi-tap;
A wireless communication module for receiving and providing an on / off control signal wirelessly transmitted through a wireless communication unit of the integrated gate; and controlling a relay switch according to an on / off control signal provided through the wireless communication module to control the user PC. A plurality of multi-taps comprising a power control module for switching the power supplied to the power switch, and a relay switch switched to supply or cut power to the user PC according to the control of the power control module; And
And a power control unit configured to control the user PC which is turned off when the power is supplied from the multi-tap and receive an on / off control signal from the power saving management server, or to turn off the user PC in the standby state. Intelligent power saving control system using a pattern recognition technology including the user PC.
5. The method of claim 4,
In the user PC,
Intelligent power saving control system using a pattern recognition technology characterized in that it further comprises a status information providing unit for transmitting its status information to the power management server.
5. The method of claim 4,
The integrated gate and the multi tap,
Intelligent power saving control system using a pattern recognition technology characterized in that for performing communication using a wireless communication such as Zigbee, Bluetooth or WLAN.
Collecting, by the pattern data collecting unit, the inactive state holding time information of the user PC to the pattern data storing unit;
Storing, by the pattern data storage unit, the deactivation state holding time information stored from the pattern data collecting unit by grouping the stored deactivation state holding time information for each time zone in a specific unit;
Calculating, by the power saving mode policy setting unit, a weight for each group; And
The power saving mode policy setting unit multiplying the average value of the inactive state maintaining time of each time unit of each specific unit by the weight of each time unit of each specific unit, and adding the result to set a power saving mode entry waiting time pattern Intelligent power saving policy setting method in intelligent power saving control system using recognition technology.
8. The method of claim 7,
The calculating of the power saving mode policy setting unit weights for each group includes:
Obtaining a value (a) obtained by squaring the number of inactive state holding times belonging to each group;
Obtaining a sum (b) of square values (a) of each group; And
In the intelligent power saving control system using a pattern recognition technology comprising the step of calculating the weight for each group by dividing the value (a) squared the number of inactive state holding time of each group by the sum value (b) How to set intelligent power saving policy.

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