KR102297007B1 - Method for standby power and power consumption of monitor and monitor for performing the same - Google Patents

Abstract

The present invention relates to a method for reducing monitor standby power and power consumption and a monitor performing such the same method. The method for reducing monitor the standby power and power consumption includes the steps of: determining, by a monitor control device, a user use signal; determining whether the monitor control device performs a power control algorithm based on the user use signal; controlling the monitor based on the power control algorithm by the monitor control device.

Description

Method for standby power and power consumption of monitor and monitor for performing the same

The present invention relates to a method for reducing monitor standby power and power consumption, and to a monitor performing such a method. More particularly, it relates to an eco-friendly monitor control method that increases energy efficiency by reducing standby power and power consumption in the monitor, and a monitor using the method.

There is a growing international interest in environmental conservation and energy conservation. In particular, the increase in air pollution due to the use of fossil fuels such as coal and oil, which are essential resources for the production of electrical energy, is becoming a global issue in line with the problem of the survival of the earth in the future. A serious problem is approaching.

In the past, energy use and environmental problems were thought to be two-fold, but recently, there is a perception that energy and environmental problems are one problem, not two, and there is a national consensus that energy conservation is the key to solving environmental problems. is being done

As interest in energy conservation increases, one of the problems that has begun to emerge is standby power in home appliances and office equipment. Standby power refers to power consumed when an electrical/electronic device is not in use or is waiting for an input from something. In the past, standby power did not mean much because the device consumes a lot of power in the operating state. is getting new

Therefore, there is a need for research on technologies for reducing standby power as well as power consumption in electronic devices.

An object of the present invention is to solve all of the above problems.

Another object of the present invention is to sequentially control the states of the monitor in order to lower the power consumption and standby power of the monitor.

In addition, the present invention aims to reduce the power consumption and standby power of the monitor in a state where there is no discomfort when using the monitor in consideration of the user's current monitor use state, and the user's signal is adaptively divided according to the power control sensitivity. do it with

A representative configuration of the present invention for achieving the above object is as follows.

According to an embodiment of the present invention, the method for reducing monitor standby power and power consumption includes the step of determining, by the monitor control device, a user use signal, whether the monitor control device performs a power control algorithm based on the user use signal. It may include determining and controlling the monitor based on the power control algorithm by the monitor control device.

Meanwhile, the user use signal may include a user use signal (active) and a user use signal (passive).

In addition, the power control algorithm includes a standby power control algorithm and a power consumption control algorithm, wherein the power consumption control algorithm is used to reduce the power consumption of the monitor before the monitor is switched to the standby power state, the standby power A control algorithm may be used to reduce power consumption of the monitor after the monitor transitions to the standby power state.

According to another embodiment of the present invention, the monitor control apparatus for reducing standby power and power consumption of the monitor includes a communication unit for communicating with the monitor and a processor operatively connected to the communication unit, wherein the processor receives a user use signal It may be implemented to determine whether to perform a power control algorithm based on the user use signal, and to control a monitor based on the power control algorithm.

Meanwhile, the user use signal may include a user use signal (active) and a user use signal (passive).

In addition, the power consumption control algorithm is used to reduce the power consumption of the monitor before the monitor is switched to the standby power state, the standby power control algorithm is the power of the monitor after the monitor is switched to the standby power state It can be used to reduce consumption.

According to the present invention, the state of the monitor can be sequentially controlled in order to lower the power consumption and standby power of the monitor.

In addition, according to the present invention, the user signal is adaptively classified according to the power control sensitivity, and the power consumption and standby power of the monitor can be reduced in a state where there is no discomfort when using the monitor in consideration of the user's current monitor use state. can

1 is a conceptual diagram illustrating a power-saving monitor control system according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.
3 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.
5 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0012] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0014] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented with changes from one embodiment to another without departing from the spirit and scope of the present invention. In addition, it should be understood that the location or arrangement of individual components within each embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description given below is not to be taken in a limiting sense, and the scope of the present invention should be taken to cover the scope of the claims and all equivalents thereto. In the drawings, like reference numerals refer to the same or similar elements throughout the various aspects.

Hereinafter, various preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those of ordinary skill in the art to easily practice the present invention.

1 is a conceptual diagram illustrating a power-saving monitor control system according to an embodiment of the present invention.

1 discloses a monitor power control system.

Referring to FIG. 1 , the monitor power control system may include a monitor control device 100 and a monitor 150 .

The monitor control apparatus 100 may include a processor that controls the operation of the monitor 150 . In a typical home computer, the computer body may be the monitor control device 100 . The monitor control device 100 may be used to include various devices connected to the monitor 150 to control the monitor 150 .

The monitor control apparatus 100 may include a communication unit for communicating with the monitor and a processor operatively connected to the communication unit, and the monitor control apparatus may perform operations for reducing power of the monitor to be described later.

The monitor control apparatus 100 may control the power used by the monitor 150 based on a power control algorithm. The power control algorithm may include a standby power control algorithm 120 and a power consumption control algorithm 110 .

The monitor control apparatus 100 may generate a monitor control signal based on the standby power control algorithm 120 and the power consumption control algorithm 110 , and transmit the monitor control signal to the monitor 150 . The monitor control signal is a signal for controlling the state of the monitor 150, and may change the power consumption generated by the monitor 150, such as ON/OFF/standby state switching of the monitor 150, brightness, color of the monitor 150, etc. It may contain possible information.

Specific standby power control algorithm 120 and power consumption control algorithm 110 will be described later.

The monitor 150 may be implemented to output an image based on the control of the monitor control apparatus 100 . The monitor 150 may be connected to the monitor control apparatus 100 to receive a monitor control signal and change the operation of the monitor 100 according to the monitor control signal.

2 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

2 discloses a method of performing monitor power control based on a standby power control algorithm and a power consumption control algorithm.

Referring to FIG. 2 , a standby power control algorithm 250 and power consumption control algorithms 210 and 220 may be selectively used for monitor power control.

Preferentially, the power consumption control algorithm 200 and the standby power control algorithm 250 may be selected based on the user's use of the monitor control unit and/or the monitor.

The power consumption control algorithm 200 and the standby power control algorithm 250 may be sequentially used according to a signal coming into the monitor control unit and a program executed by the monitor control unit.

The power consumption control algorithm 200 may be used when it is necessary to save power consumption of the monitor under a situation in which the standby power control algorithm 250 is not used. The power consumption control algorithm 200 is used to reduce the power consumption of the monitor before switching to the standby power state, and the standby power control algorithm 250 can be used to reduce the power consumption of the monitor after switching to the standby power state. have.

The power consumption control algorithm 200 may include a first power consumption control algorithm 210 and a second power consumption control algorithm 220 .

The first power consumption control algorithm 210 may be used when a user use signal is generated during the power consumption threshold time 215 . The first power consumption control algorithm 210 is an algorithm used when a user use signal is generated, and may be performed in consideration of a program currently executed by a user and a user use signal.

The second power consumption control algorithm 220 is an algorithm used immediately before the standby power control algorithm 250 and may be performed when a user use signal does not occur during the power consumption threshold time 215 . The power consumption threshold time 215 may be shorter than the standby power threshold time 225 , and after the power consumption threshold time 215 , the second power consumption control algorithm 220 is performed, and the standby power threshold time 225 . ), the standby power control algorithm 250 may be used.

The standby power control algorithm 250 may be applied when it is determined that the user will not use the monitor control unit and/or the monitor for a certain period of time. In other words, the standby power control algorithm 250 may be applied when a user use signal on the monitor control unit and/or the monitor is not generated during the standby power threshold time 225 . The user use signal may be a specific signal input through the user interface or a signal indicating the user's use of the monitor controller/monitor, such as a signal generated by the operation of a program executed by the user.

When there is no user use signal, the monitor power control may be performed while changing to the first power consumption control algorithm 210 , the second power consumption control algorithm 220 , and the standby power control algorithm 250 .

3 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

3 discloses a method of determining a signal used by a user for performing a standby power control algorithm and a power consumption control algorithm.

Referring to FIG. 3 , the determination of whether a user use signal is generated may be determined according to the power control sensitivity 300 .

The power control sensitivity 300 relates to how sensitively to control the power of the monitor, and as the power control sensitivity 300 is relatively high, the power control sensitivity 300 may operate such that the power is reduced relatively much under the same circumstances.

When the power control sensitivity 300 is relatively high, the range determined by the generation of the user use signal 350 may be relatively wide, and when the power control sensitivity 300 is relatively low, the user use signal 350 . The range determined by the occurrence of may be relatively narrow.

Specifically, the signal that can be determined as the user use signal 350 may include a signal input through a user interface (eg, keyboard, mouse), a signal generated on a program executed by the user, and the like.

According to an embodiment of the present invention, a signal input through a user interface (eg, keyboard, mouse) may be expressed in terms of a user use signal (active) 315 . A signal generated on a program executed by a user may be expressed in terms of a user use signal (passive) 317 .

The user use signal (active) 315 may be determined as the user use signal 350 regardless of the power control sensitivity 300 . The user use signal (passive) 317 may be determined as a user use signal in consideration of power consumption control sensitivity.

The user use signal (passive) 317 is displayed on the current monitor among the user use signal (passive, display) 319 related to the program currently displayed on the monitor among the programs executed by the user and the program executed by the user It may be divided into a user use signal (passive, non-display) 345 related to a non-programmed program.

The user use signal (passive, display) 319 is expressed as a user use signal (passive, main display) 325 when there is a ratio greater than or equal to the threshold screen in consideration of the ratio of the executed program being displayed on the screen, and the critical screen If there is less than the ratio, it may be expressed as a user use signal (passive, sub-display) 335 .

For example, if it is assumed that the power control sensitivity 300 is in 4 steps (steps 1 to 4), and the power control sensitivity 300 increases as the step 1 to 4 moves, it is determined as the user use signal 350 . The signal can be set as follows.

When the power control sensitivity 300 is level 1, the power control algorithm may be performed by determining only the user use signal (active) 315 as the user use signal 350 .

When the power control sensitivity 300 is the second stage, the power control algorithm is performed by determining the user use signal (active) 315 and the user use signal (passive, main display) 317 as the user use signal 350 . can

When the power control sensitivity 300 is three levels, a user use signal (active) 315, a user use signal (passive, main display) 325 and a user use signal (passive, sub display) 335 are used by the user A power control algorithm may be performed by judging by the signal 350 .

When the power control sensitivity 300 is 4 levels, the user use signal (active) 315, the user use signal (passive, main display) 325, the user use signal (passive, sub display) 335 and the user use A power control algorithm may be performed by determining the signal (passive, non-display) 345 as the user use signal 350 .

In this way, the user use signal 350 for performing the power control algorithm is determined according to the power control sensitivity 300, and the standby power control algorithm 370 and the power consumption control algorithm ( 360) can be performed.

Also, according to an embodiment of the present invention, the power control sensitivity 300 may be set differently in the standby power control algorithm 370 and the power consumption control algorithm 360 .

For example, in the power consumption control algorithm 360 , the power control sensitivity 300 may be set to four levels, and in the standby power control algorithm 370 , the power control sensitivity 300 may be set to one level.

That is, in the state in which the power consumption control algorithm 360 is performed, the power control sensitivity 300 is set to be relatively high to reduce the inconvenience of the user's device use due to erroneous judgment, and the standby power control algorithm 370 can be used. In the performing state, the power control sensitivity 300 may be set relatively low to respond only to the user use signal (active) 315 which is an active signal generated by the user.

4 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

4 discloses a power consumption control algorithm among a standby power control algorithm and a power consumption control algorithm. In particular, a method for performing a first power consumption control algorithm is disclosed.

Referring to FIG. 4 , the power consumption control algorithm may be used when it is necessary to save power consumption of the monitor under a situation in which the standby power control algorithm is not used.

As described above, among the power consumption control algorithms, the first power consumption control algorithm may be used when a user use signal is generated during the power consumption threshold time 450 .

In the first power consumption control algorithm, power consumption on the monitor may be reduced by controlling the luminance and/or color of an image output on the monitor.

In the first power consumption control algorithm, when a user use signal is not generated in a critical time unit, luminance and color on the monitor may be sequentially adjusted. As time passes sequentially in the critical time (step 1) 410, the critical time (step 2) 420, ??, and the critical time (step n), the luminance on the monitor may be lowered step by step.

The threshold time may be shorter than the power consumption threshold time 450 for switching to the second power consumption control algorithm.

For example, after the last user use signal generation time 400, if the threshold time (1 step) 410 has passed, the first step luminance 415 is set, and after the last user use signal generation time 400 When the threshold time (2 steps) 420 has passed, the second level brightness 425 is set, and when the threshold time (n steps) has passed since the last user use signal generation time 400, it can be set to the nth level brightness have.

In the case of a color, it may be changed like a luminance after a set threshold step has passed. For example, when the set threshold step is the third step 430 , the color of the image output on the monitor may be adjusted along with the luminance from the critical time (step 3) 430 . The color may also be changed to a color of a low temperature, such as the first level color 455 , the second level color, ??, and the nth level color.

That is, in the first power consumption control algorithm, the brightness and/or color on the monitor may be sequentially adjusted according to the flow of the power consumption control threshold time, which is a set threshold time, and power consumption generated by the monitor may be reduced.

The above change may be reset to the original screen state before adjusting the luminance and color when the user use signal (active) is generated again.

5 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

In FIG. 5 , a power consumption control algorithm among a standby power control algorithm and a power consumption control algorithm is disclosed. In particular, a method for performing a second power consumption control algorithm is disclosed.

Referring to FIG. 5 , after the first power consumption control algorithm 510 is performed, if a user use signal is not generated for a power consumption threshold time 515 , the second power consumption control algorithm 520 may be switched. have.

The second power consumption control algorithm 520 may output an image using only a partial region of the monitor.

A partial area of the monitor used in the second power consumption control algorithm 520 may be expressed as an output limiting area 550 .

For example, if the total area of the monitor is 1, only a 1/4 area of the monitor is set as the output limiting area 550 to output an image, and an image may not be output on the remaining 3/4 area. That is, power consumption generated by the monitor may be reduced by reducing the output limiting region 550 , which is an area used by the monitor, and switching the remaining areas to an off state.

In this case, the size of the output limiting area 550 used in the monitor may be set differently according to a currently executed program. First, it can be divided into an output program currently being output on the monitor and a non-output program not being output on the current monitor.

On the main display area 560 of the output limitation area 550 , the screen of the output program may be divided and output, and information on the non-output program may be output on the sub display area 570 of the output limitation area 550 . .

The second power consumption control algorithm 520 may be performed from after the power consumption threshold time 515 elapses until the standby power threshold time 525 before the standby power control algorithm 530 is performed.

The output limiting region 550 may be reduced according to the passage of time from the elapse of the power consumption threshold time 515 until the standby power threshold time 525 .

Similarly, the above change may be reset to the original screen state before adjusting the luminance and color before the size of the output limiting region 550 output from the monitor decreases, when the user use signal (active) is generated again afterward.

6 is a conceptual diagram illustrating a power control algorithm according to an embodiment of the present invention.

6 discloses a standby power control algorithm among a standby power control algorithm and a power consumption control algorithm.

Referring to FIG. 6 , when a user use signal is not input during a standby power threshold time, a standby power control algorithm may be performed.

The standby power control algorithm may include a standby power control algorithm (step 1) 610 and a standby power control algorithm (step 2) 620 .

In the standby power control algorithm (step 1) 610, information about the current program is output on the output limiting area 650 on the monitor, but may be output in the form of a captured image. That is, an image reflecting the currently executed program is not output, but a still captured image 640 is output to provide information on the program currently used by the user. The captured image 640 may be periodically captured based on a set period and output on the output limiting area 650 . In the standby power control algorithm (Step 1) 610, the size, color, and luminance of the captured image may be changed to the color and luminance to save power consumption according to the passage of time.

The standby power control algorithm (step 2) 620 may be performed when the user use signal is not generated for a threshold time after the standby power control algorithm (step 1) 610 is performed. In the standby power control algorithm (step 2) 620, the monitor may be switched to a sleep mode, and an image may not be output from the monitor.

Similarly, the above change may be reset to the original screen state before adjusting the luminance and color before the size of the output limiting area 650 output from the monitor decreases when the user use signal (active) is generated again afterward.

The embodiments according to the present invention described above may be implemented in the form of program instructions that can be executed through various computer components and recorded in a computer-readable recording medium. The computer-readable recording medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the computer-readable recording medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include hard disks, magnetic media such as floppy disks and magnetic tapes, optical recording media such as CD-ROMs and DVDs, and magneto-optical media such as floppy disks. medium), and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. A hardware device may be converted into one or more software modules to perform processing in accordance with the present invention, and vice versa.

In the above, the present invention has been described with reference to specific matters, such as specific components, and limited embodiments and drawings, but these are only provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. Those of ordinary skill in the art to which the invention pertains can make various modifications and changes from these descriptions.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and the scope of the spirit of the present invention is not limited to the scope of the scope of the present invention. will be said to belong to

Claims (6)

How to reduce monitor standby power and power consumption,
determining, by the monitor control device, a user use signal;
determining, by the monitor control device, whether to perform a power control algorithm based on the user use signal; and
Comprising the step of the monitor control device controlling the monitor based on the power control algorithm,
The user use signal includes a user use signal (active) or a user use signal (passive),
The power control algorithm includes a standby power control algorithm and a power consumption control algorithm,
the power consumption control algorithm is used to reduce power consumption of the monitor before the monitor enters a standby power state;
the standby power control algorithm is used to reduce the power consumption of the monitor after the monitor switches to the standby power state;
The user use signal (active) is a signal input through a user interface,
The user use signal (passive) is a signal generated by a program executed by the user,
The user use signal (active) is determined to be the user use signal regardless of power control sensitivity,
The user use signal (passive) is determined to be the user use signal in consideration of the power control sensitivity,
The user use signal (passive) includes a user use signal (passive, display) related to a program currently displayed on the monitor among programs executed by the user and a program executed by the user that is not currently displayed on the monitor. contains user use signals (passive, non-display) related to non-programming;
The user use signal (passive, display) is the ratio between the user use signal (passive, main display) and the ratio below the threshold screen when there is a ratio greater than or equal to the threshold screen in consideration of the ratio in which the program executed by the user is displayed on the screen Including a user use signal (passive, sub-display) that is the case,
When the power control sensitivity is level 1, only the user use signal (active) is determined as the user use signal and the power control algorithm is performed,
When the power control sensitivity is the second stage, the user use signal (active) and the user use signal (passive, main display) are determined as the user use signal, and the power control algorithm is performed,
When the power control sensitivity is three levels, the user use signal (active), the user use signal (passive, main display), and the user use signal (passive, sub display) are determined as the user use signal, so that the power control algorithm is performed,
When the power control sensitivity is 4 levels, the user use signal (active), the user use signal (passive, main display), the user use signal (passive, sub-display), and the user use signal (passive, non-display) ) is determined as the user use signal, and the power control algorithm is performed. According to claim 1,
The power consumption control algorithm includes a first power consumption control algorithm and a second power consumption control algorithm,
The first power consumption control algorithm is used when the user use signal is generated during a power consumption threshold time,
The second power consumption control algorithm is used when the user use signal does not occur during the power consumption threshold time,
The standby power control algorithm is used when the user use signal on the monitor is not generated for a standby power threshold time,
The first power consumption control algorithm sequentially adjusts luminance and color on the monitor when the user use signal is not generated in a threshold time unit,
The second power consumption control algorithm outputs an image by setting only a partial area of the monitor as an output limiting area,
The size of the output limiting area is set differently according to a program currently being executed. 3. The method of claim 2,
The screen of the output program is divided and output on the main display area among the output limitation areas,
Information on a non-output program is output on a sub-display area of the output limitation area,
The output program is a program currently being output on the monitor,
The method of claim 1, wherein the non-output program is a program that is not currently being output on the monitor. A monitor control device for reducing monitor standby power and power consumption,
a communication unit for communicating with the monitor; and
Including a processor operatively connected to the communication unit
The processor determines a user use signal,
Determining whether to perform a power control algorithm based on the user use signal,
Implemented to control the monitor based on the power control algorithm,
The user use signal includes a user use signal (active) or a user use signal (passive),
The power control algorithm includes a standby power control algorithm and a power consumption control algorithm,
the power consumption control algorithm is used to reduce power consumption of the monitor before the monitor enters a standby power state;
the standby power control algorithm is used to reduce the power consumption of the monitor after the monitor switches to the standby power state;
The user use signal (active) is a signal input through a user interface,
The user use signal (passive) is a signal generated by a program executed by the user,
The user use signal (active) is determined to be the user use signal regardless of power control sensitivity,
The user use signal (passive) is determined to be the user use signal in consideration of the power control sensitivity,
The user use signal (passive) includes a user use signal (passive, display) related to a program currently displayed on the monitor among programs executed by the user and a program executed by the user that is not currently displayed on the monitor. contains user use signals (passive, non-display) related to non-programming;
The user use signal (passive, display) is the ratio between the user use signal (passive, main display) and the ratio below the threshold screen when there is a ratio greater than or equal to the threshold screen in consideration of the ratio in which the program executed by the user is displayed on the screen Including a user use signal (passive, sub-display) that is the case,
When the power control sensitivity is level 1, only the user use signal (active) is determined as the user use signal and the power control algorithm is performed,
When the power control sensitivity is the second stage, the user use signal (active) and the user use signal (passive, main display) are determined as the user use signal, and the power control algorithm is performed,
When the power control sensitivity is three levels, the user use signal (active), the user use signal (passive, main display), and the user use signal (passive, sub display) are determined as the user use signal, so that the power control algorithm is performed,
When the power control sensitivity is 4 levels, the user use signal (active), the user use signal (passive, main display), the user use signal (passive, sub-display), and the user use signal (passive, non-display) ) is determined as the user use signal and the power control algorithm is executed. 5. The method of claim 4,
The power consumption control algorithm includes a first power consumption control algorithm and a second power consumption control algorithm,
The first power consumption control algorithm is used when the user use signal is generated during a power consumption threshold time,
The second power consumption control algorithm is used when the user use signal does not occur during the power consumption threshold time,
The standby power control algorithm is used when the user use signal on the monitor is not generated for a standby power threshold time,
The first power consumption control algorithm sequentially adjusts luminance and color on the monitor when the user use signal is not generated in a threshold time unit,
The second power consumption control algorithm outputs an image by setting only a partial area of the monitor as an output limiting area,
The size of the output limiting area is set differently according to a currently executed program. 6. The method of claim 5,
The screen of the output program is divided and output on the main display area among the output limitation areas,
Information on a non-output program is output on a sub-display area of the output limitation area,
The output program is a program currently being output on the monitor,
The non-output program is a monitor control device, characterized in that the program is not currently output on the monitor.

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