KR100786077B1 - The display device for reducing the consumed wattage of Display Power Manegement mode and method for controlling the same - Google Patents

Abstract

The present invention relates to an image device capable of reducing power consumption in a power saving mode for solving the problem that unnecessary power consumption is wasted in a display power management (DPM) mode and the like, and a control method thereof. According to an aspect of the present invention, there is provided a video device including a transistor for supplying power to each IC of a main board, wherein the video device is determined whether or not the video device is in a power saving mode. And a control unit for controlling the transistor not to supply power to each IC of the main board, and a dedicated transistor for supplying constant power only to the control unit regardless of whether it is in the power saving mode or not. Provided is an image device capable of reducing power consumption in modes. Therefore, according to the present invention, there is an effect that the power consumption in the power saving mode can be greatly reduced in a video device, especially a large monitor or a TV.

Display Power Management (DPM), Transistor

Description

The display device for reducing the consumed wattage of Display Power Mangement mode and method for controlling the same}

1 is a block diagram showing a configuration of a video device according to the prior art;

2 is a block diagram illustrating a configuration of an image device capable of reducing power consumption in a power saving mode according to the present invention.

3 is a flowchart (flow chart) showing a control method of an image device capable of reducing power consumption in a power saving mode according to the present invention.

* Description of the symbols for the main parts of the drawings *

101,201: Video device 102,202: Power board

103,203: Transistor 104,204: Switching part

105,205: Micom 106,206: Main Board

107,207: IC (Integrated Circuit)

108,208: Micom 209: microcomputer-only transistor

The present invention relates to an image device, and more particularly, to an image device and a control method thereof capable of reducing power consumption in a power saving mode (DPM mode, etc.).

With the development of video devices, in recent years, not only TV broadcasts can be watched by the video devices, but also various A / V (Audio / Video) signals can be input and output from an external input device connected to the video devices. It can even be used for PC work.

In particular, when the video device is used for PC work, by implementing a power saving mode (Display Power Management mode), unnecessary power consumption is reduced. The power saving mode is set to use the video device for PC work, but when the input of a mouse, a remote control, or a local key does not exist for a predetermined time, the screen of the video device is temporarily turned off. off).

1 is a block diagram showing the configuration of a video device according to the prior art. Hereinafter, an operation process of a transistor for supplying power in a power saving mode in a conventional video device will be described with reference to FIG. 1.

In general, the power board 102 of the imaging device 101 receives an alternating current voltage, and the transistor 103 in the power board 102 supplies power to each IC 107 of the main board 106. To supply.

The IC 107 in the main board 106 is operated by receiving power from the transistor 103.

In addition, the microcomputer 108 in the main board 106 controls the IC 107 in the main board 106, determines whether the video device 101 is in a power saving mode, and provides information on the determination result. Is transmitted to the microcomputer 105 in the power board 102.

Meanwhile, the microcomputer 105 in the power board 102 controls the switching unit 104 connecting the transistor 103 and each IC 107 so as to supply power to a specific IC. However, the microcomputer 105 may be controlled by the microcomputer 108 in the main board 106.

When the video device 101 is in the power saving mode, the transistor 103 is in an activated state, but under the control of the microcomputer 108 in the main board 106, the microcomputer in the power board 102 is controlled. 105 switches off the switching unit 104 that connects the transistor 103 and each IC 107. Of course, only the path is switched on so that power is supplied to the microcomputers 105 and 108.

However, the above-described conventional video device has the following problems.

For example, the microcomputer 108 in the main board 106 operates under 5V power. Regardless of whether the state of the image device 101 is in a power saving mode, the microcomputer 108 should always be supplied with power, and thus the transistor 103 should always be in an active state.

In addition, the capacity of the transistor is generally determined by a full load of the system. For example, the transistor 103 of the imaging apparatus 101 may have a capacity of about 2 to 3 A.

However, in the power saving mode (DPM mode, etc.), the power required by the main board 106 is about 5V, and a very small current of about 100mA is required.

In this case, in particular, a problem of the conventional video apparatus occurs.

In general, when a full load is applied to the transistor, the efficiency reaches 90%, but when the load is low, the efficiency is reduced to about 40 to 50%.

That is, as described above, when a very small load of about 100 mA is applied in the power saving mode, the theoretical power consumption (W) is 0.5W (power consumption (W) = power supply (5V) x current (100mA)). = 0.5W), when the load is small, the efficiency is reduced to about 50%, there was a problem that the actual power consumption (W) must rise to about 1 (Watt).

In particular, the video device such as a large monitor TV has a plurality of transistors, and since the use of a large capacity transistor, such a problem is more serious.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to reduce power consumption in a power saving mode (DPM mode) and a control method thereof, which can minimize unnecessary power consumption in a power saving mode. To provide.

In order to achieve the above object, the present invention provides a video device having a transistor for supplying power to each IC of the main board, it is determined whether the video device is in a power saving mode, the determination result, A control unit for controlling the transistor not to supply power to each IC of the main board in a power saving mode state, and a dedicated transistor for supplying constant power only to the control unit regardless of whether it is in the power saving mode state. Provided is an image device capable of reducing power consumption in a power saving mode, characterized in that made.

Preferably, the dedicated transistor has a minimum capacity capable of activating the controller.

The control unit may include a microcomputer of a main board determining whether the video device is in a power saving mode, and when the video device is in a power saving mode, the transistor supplies power to each IC of the main board. It is desirable to include a microcomputer of the power board to control so as not to.

In order to achieve the above object, the present invention provides a control method of a video device having a transistor for supplying power to each IC of the main board, the control unit, and determines whether the video device is in a power saving mode, the determination As a result, when the image device is in the power saving mode, controlling the transistor not to supply power to each IC of the main board, and whether or not in the power saving mode, through the dedicated transistor, the controller It provides a control method of an imaging device that can reduce the power consumption of the power saving mode, characterized in that it comprises a step of supplying a constant power only.

Preferably, the dedicated transistor has a minimum capacity capable of activating the controller.

The control unit may include a microcomputer of a main board determining whether the video device is in a power saving mode, and when the video device is in a power saving mode, the transistor supplies power to each IC of the main board. It is desirable to include a microcomputer of the power board to control so as not to.

Therefore, according to the present invention, there is an effect that the power consumption in the power saving mode can be greatly reduced in a video device, especially a large monitor or a TV.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

2 is a block diagram illustrating a configuration of an image device capable of reducing power consumption in a power saving mode according to the present invention. Referring to FIG. 2, a method of reducing power consumption in a power saving mode by a component of an imaging apparatus according to the present invention will be described below. Unlike the prior art, there is a technical feature of the present invention in that a small dedicated transistor for supplying power to the microcomputer is added.

The imaging device 201 includes a power board 202 and a main board 206. However, in general, a component that receives and outputs a broadcast signal and receives and outputs a PC signal has been omitted, and the components related to the present invention have been mainly shown. However, those skilled in the art will readily appreciate the present invention through the accompanying drawings. I can understand it.

The power board 202 includes a transistor 203, a switching unit 204, a microcomputer 205, and a microcomputer dedicated transistor 209. When the image device 201 is in a power saving mode, the power board 202 is input. AC power is supplied to the main board 206 through the microcomputer dedicated transistor 209.

The main board 206 includes ICs 207 implementing various functions, and a microcomputer 208. The main board 206 receives power from the power board 202 and executes functions set for each IC. It plays a role.

When the image device 201 is in normal operation (not in the power saving mode), when AC power is input to the power board 202, power is supplied to each IC 207 through the transistor 203. .

However, when the imaging device 201 is in the power saving mode, AC power is supplied to the microcomputer dedicated transistor 209, and the microcomputer dedicated transistor 209 supplies the input AC power to the microcomputer 208 in the main board 206. To pass.
Accordingly, the microcomputer 208 in the main board 206 determines that the state of the video device 201 is a power saving mode, and transmits the same to the microcomputer 205 in the power board 202.
In addition, the microcomputer 205 having received the image device 201 in the power saving mode maintains only the power supply supplied from the microcomputer dedicated transistor 209 to the microcomputer 208, and the power supplied through the other transistor 203. Blocks.

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However, even when the image device 201 is in a power saving mode, the microcomputer-only transistor 209 supplies power to the microcomputer 208 to maintain whether an input signal is applied. Should be.

At this time, unlike the prior art, a power source is supplied to the microcomputer 208 through the microcomputer dedicated transistor 209 by adding the microcomputer dedicated transistor 209.

The microcomputer-only transistor 209 has a minimum capacity for activating the microcomputer 208 in terms of minimizing power consumption in the power saving mode.

That is, in the power saving mode, power is not supplied to the microcomputer 208 through the transistor 203, but power is supplied to the microcomputer 208 through the microcomputer-only transistor 209 having a small capacity. Effect occurs.

For example, assume that the microcomputer-only transistor 209 has a 150 to 200 mA capacity, and the transistor 203 has a capacity of about 2 to 3 A.

As assumed in the description of FIG. 1, in the power saving mode (DPM mode, etc.), the power required by the main board 206 is about 5V, and a very small current of about 100mA may be required.

If the transistor 203 is used as in the related art, compared with the capacitance (2 to 3A) of the transistor 203, since the 100 mA required for the power saving mode is a very small current, the efficiency is greatly reduced (Fig. 1). See description for).

However, if the microcomputer-only transistor 209 is used as in the present invention, the capacitance (150-200mA) of the microcomputer-only transistor 209 and 100 mA required for the power saving mode do not differ significantly, and thus power consumption is reduced. The efficiency is maintained at about 90%.

Therefore, the theoretical power consumption (W) is 0.5W (power consumption (W) = power supply (5V) x current (100mA) = 0.5W), the efficiency is maintained at about 90%, the actual power consumption is also about 0.56W. (Actual power consumption (0.56W) = theoretical power consumption (0.5W) x 1 / efficiency (0.9)).

When comparing the descriptions of Fig. 1 (prior art) and Fig. 2 (invention), the same value is assumed. As a result, in the power saving mode, the conventional technology consumes about 1 Watt, but the present invention consumes about 0.56 Watt. As can be seen, the present invention has the effect of significantly reducing the power consumption in the power saving mode as compared to the past.

3 is a flowchart (flow chart) illustrating a control method of an image device capable of reducing power consumption in a power saving mode according to the present invention. Referring to FIG. 3, a control method of an image device capable of reducing power consumption in a power saving mode according to the present invention will be described.

However, the video device according to the present invention will be described in detail with reference to FIG. 2, and the control method of the video device will be briefly described.

The power of the video device may be turned on by input of a remote controller or a local key (S301). After the power of the video device 201 is turned on, a general broadcast screen may be output or the video device 201 may be used for PC work.

It is determined whether the video device 201 is in a power saving mode (S302). However, in the power saving mode, for example, when the image device 201 is used for PC work, and an input such as a mouse, a remote controller, or a local key does not exist for a predetermined time or more, a screen of the image device 201 is used. This may mean temporarily turning off.

As a result of the determination (S302), when the image device 201 is in the power saving mode, the microcomputer 208 of the main board 206 determines that the image device 201 is in the power saving mode. The microcomputer 205 may transmit a feedback signal (S303).

The microcomputer 205 of the power board 202 receiving the feedback signal maintains only the power supply supplied from the microcomputer dedicated transistor 209 to the microcomputer 208, and supplies the power supplied through the other transistor 203. Is blocked (S304). However, the microcomputer dedicated transistor 209 is set to continuously supply the minimum power for the microcomputer 208 to be activated regardless of whether the image device 201 is in a power saving mode. Accordingly, the microcomputer 208 may perform steps S302 and S303 even in a power saving mode state, that is, even when power is not supplied to the general IC.

The present invention is not limited to the above-described embodiments, and as can be seen in the appended claims, modifications can be made by those skilled in the art to which the invention pertains, and such modifications are within the scope of the present invention.

And, the above-mentioned numerical value is a preferred embodiment or merely an example, the scope of the present invention is not limited to the numerical values, and as can be seen in the appended claims, Modifications are possible by those skilled in the art and such modifications are within the scope of the present invention.

The effects of the video device and its control method which can reduce power consumption in the power saving mode (DPM mode) according to the present invention described above are as follows.

The present invention has the effect of minimizing unnecessary power consumption in the power saving mode, and by adding a microcomputer dedicated transistor of a small capacity to the power board, rather than trying to reduce the load on the conventional main board, The reduction is much more effective.

Claims (6)

In a video device having a transistor for supplying power to each IC of the main board, The controller determines whether the image device is in a power saving mode, and when the image device is in the power saving mode, controls to cut off power supply of the transistor so that power is not supplied to each IC of the main board. ; And An image device capable of reducing power consumption in a power saving mode including a dedicated transistor for supplying constant power to only the control unit regardless of whether the power saving mode is in the power saving mode. The method of claim 1, The dedicated transistor, And a power consumption in a power saving mode, characterized in that it has a minimum capacity for activating the control unit. The method of claim 1, The control unit, A microcomputer of the main board determining whether the video device is in a power saving mode; and If the image device is in the power saving mode, the determination result includes a microcomputer of the power board to cut off the power supply of the transistor to control the power supply to each IC of the main board. Imaging devices that can reduce power consumption. In the control method of a video device having a transistor for supplying power to each IC of the main board, Determining whether the video device is in a power saving mode, and when the video device is in a power saving mode, controlling the power supply to each IC of the main board by not supplying power supplied through the transistor; And Regardless of whether it is in the power saving mode, the control method of the imaging device can reduce the power consumption of the power saving mode comprising the step of maintaining a constant power supplied from the dedicated transistor. The method of claim 4, wherein The dedicated transistor, The control method of the video device to reduce the power consumption of the power saving mode, characterized in that it has a minimum capacity to activate the control unit. The method of claim 4, wherein Controlling the supply of power, Determining, by the main board, a power saving mode state of the video device and transmitting the same to a microcomputer of a power board; Controlling the power consumption of the power saving mode of the power saving mode, characterized in that the microcomputer of the power board received the power saving mode state of the video device is cut off the power supplied from the transistor.

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