KR20020084568A - Method for controlling power of Monitor - Google Patents

Abstract

PURPOSE: A monitor power control method is provided to control the power consumption in two stages of normal mode and power saving mode without any standby mode, thereby saving more power consumption. CONSTITUTION: A monitor power control method includes the steps of determining normal mode or a power saving mode, supplying power to every circuit in case of normal mode, displaying a warning message of advancing to power saving mode, and turning off every electric circuit including the cathode heater power which operate alternatively by a power control element if no key input of a user is sensed after a predetermined standby time in the other case(13S-16S).

Description

Method for controlling power of Monitor

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an automatic power saving method, and more particularly, to a power control method of a monitor that minimizes power consumption of a computer video monitor.

Typical color video monitors consume about 50 to 80 percent of the total PC consumption.

Such monitors dissipate most of the energy consumed from the screen fluorescent surface to visible light emission, heat consumption, electromagnetic radiation, high energy radiation and acoustic energy, but only fluorescent surface emission is useful and only useful when viewed by the viewer.

Health problems when exposed to such radiation rashes for a long time have been an issue, and monitor makers have spent a lot of research money to reduce radiation rashes on monitors.

In addition, the use of PCs continues to increase and is now a major consumer of electrical energy. The US Environmental Protection Agency is pressing computer producers to develop new systems to increase energy efficiency. Thus, low-voltage ICs and microcomputer power management technologies have contributed to reducing consumption when the computer is not in use. However, improving the energy efficiency of a PC is not an easy task until a suitable alternative to the CRT or a more efficient CRT is available.

What is needed is a way to shut down the monitor's high energy consumption circuitry when the display is not in use. This is determined by the period of inactivity from input devices such as modems, mice, keyboards, and the like. Many computers and monitor terminals use technologies such as screen blanking circuitry and screen saver functions. In other words, pressing a key or moving the mouse activates the previous screen again. The technology can signal the monitor's microcomputer to reduce monitor power consumption or add a device for a "dumb" monitor to bring down or recover some or all of the monitor's power circuitry. One way to achieve this result is to apply a signal to bring the monitor down to some predetermined level without adding to the signal currently provided to the monitor.

The power saving device and method of a conventional computer monitor using the above principle will be described with reference to the accompanying drawings.

1 is a block diagram showing a power saving device of a conventional computer monitor.

That is, the interface unit 2 which is connected to the PC and the VGA cable 1 and separates and outputs the color signals (R, G, B) and the synchronization signal (vertical synchronization signal and horizontal synchronization signal) input from the PC, Power consumption controller that monitors the synchronization signal output from the interface unit 2 and controls the power of the monitor in the normal mode, the stand-by mode, the suspend mode, and the off mode. (3) and a power control circuit to input a color signal output from the interface unit 1 and a synchronization signal through the controller 3, and according to the mode control signal of the controller 2, the CRT ( And a video circuit section 4 for supplying a video signal and power to the device (not shown).

The operation of the conventional power saving monitor configured as described above is as follows.

2 is an operation flowchart of a conventional monitor power saving control method.

That is, the controller 3 monitors the synchronization signal output from the interface unit 2 to determine the mode (1S).

As a result of the determination, if vertical and horizontal synchronization signals are normally input from the PC (2S), it is determined as a normal mode and the first level signal Level 1 and the second level signal Level 2 are normally output and the video is output. Through the circuit section 4, all the circuits are turned on (3S).

In addition, the controller 3 monitors the synchronization signal output from the interface unit 2 and if the vertical synchronization signal is not normally input from the PC or the horizontal synchronization signal is not normally input (4S), the power saving mode, In the standby mode or the suspend mode, the first level signal Level 1 or the second level signal Level 2 is changed and output. Thus, the video circuit section 4 turns off all power circuits selectively operated by all power control means except for the power supplied to the cathode heater of the CRT (5S). That is, the controller 3 counts the horizontal synchronizing signal generated between each pair of vertical synchronizing signals, and changes the second level signal if there is no horizontal synchronizing signal, and the interval count of the horizontal synchronizing signal is the maximum video scan of the monitor. If the ratio is greatly exceeded, it is determined that there is no vertical synchronization signal and the first level signal is changed. As such, when one of the first and second level signals is changed, all power circuits selectively operated by all power control means except the heater power are turned off. At this time (power saving mode), the power consumption of the monitor is reduced by about 80% to 90%.

When all of the synchronization signals are normally input in the power saving mode, the controller 3 recognizes the normal mode again and outputs the first and second level signals to the normal mode, thereby reactivating the monitor. At this time, the reactivation of the monitor in the standby mode takes 5 seconds or less since power is supplied to the heater as described above.

The controller 3 determines the off mode when all the synchronization signals are not input from the PC (6S), and changes both the first and second level signals to control the cathode heater power of the CRT as well as the power control means. Turn off all power circuits selectively operating (7S). Monitor power consumption in this off mode is reduced by more than 98%.

This process is repeated if the main power is not cut off.

As described above, the conventional monitor power saving method has the following problems.

First, there is a limit in reducing power consumption because the power of the monitor is controlled in three steps by determining the state of the vertical and horizontal synchronization signal. That is, since the power is supplied to the heater in the standby mode or the suspend mode, power consumption by the heater is not reduced.

Second, when the monitor is reactivated while the monitor is turned off, including the heater power which is in the off mode, it takes a long time to heat up the cathode's heater. This takes

Third, while the user does not actually stop using the computer for a while while doing other things, the user suddenly turns off the computer without knowing it and turns off the computer, causing inconvenience to the user.

The present invention has been made to solve the above problems, by controlling the power of the monitor in two stages according to the use of the PC, further reduce the power consumption and shorten the time required to reactivate, and enters the power saving mode to the user Its purpose is to provide a power control method for a monitor so that it can be notified.

1 is an internal configuration diagram of a general monitor

2 is a flow chart of a power control operation of a conventional monitor

3 is a flowchart illustrating a power control operation of a monitor according to the present invention.

4 is a power control timing diagram of a monitor according to the present invention.

In accordance with another aspect of the present invention, there is provided a power control method of a monitor, including determining a normal mode or a power saving mode, supplying power to all circuits when the normal mode is determined, and determining a power saving mode. Displaying a warning message for entering the power saving mode and waiting for a predetermined time to turn off all power circuits selectively operated by the power control means as well as the cathode heater power when the user's key input is not detected. do.

In addition, in the power control method of the monitor according to the present invention, when the transition from the power saving mode to the normal mode, the cut-off voltage is maintained at a voltage of 0V for a predetermined time, the grid voltage is applied so that the hot electrons are discharged to the maximum It is another feature that further comprises the step of.

The displaying of the warning message of the present invention may further include displaying a waiting time count state for entering the power saving mode.

The power control method of the monitor of the present invention having such a feature will be described in detail with reference to the accompanying drawings as follows.

First, since the hardware configuration of the PC monitor of the present invention is the same as the conventional method, the power control method of the monitor of the present invention is described as follows.

3 is an operation flowchart of a monitor power control method according to the present invention, Figure 4 is a power supply timing chart when reactivation according to the present invention.

First, the monitor power control method of the present invention is controlled in two phases, a normal mode and a power saving mode.

In other words. As shown in FIG. 3, the controller 3 monitors the synchronization signal output from the interface unit 2 (11S).

Then, it is determined whether the vertical synchronization signal or the horizontal synchronization signal is normally input from the PC (12S), and if one of the horizontal and vertical synchronization signals is not normally input or not all the synchronization signals are normally input, the power saving mode is determined ( 12S), as shown in Fig. 4, a warning message that the computer enters the power saving mode from the time when the synchronization signal abnormal detection is detected, for example, "when there is no key input within about 10 seconds from now, enter the power saving mode" The message is displayed and the waiting time for entering the power saving mode under the warning message is counted in reverse, such as 10, 9, 8, etc. (13S).

Subsequently, it is determined whether a key signal is input within the waiting time (14S), and when the key signal is input, the process returns to the synchronization signal monitoring step 11S. If the key signal is not input, the first and second level signals are all changed to All power circuits selectively operated by the power control means as well as the cathode heater power source of the CRT are turned off (15S). That is, all power supplies are 0V and the voltage applied to the grid electrode is grounded (GND).

Monitor power consumption in such a power saving mode is reduced by more than 98%.

On the other hand, if the vertical and horizontal synchronization signals are normally input from the determination result 12S, it is determined that the normal mode and whether or not the normal mode is switched from the power saving mode (17S).

As a result of the determination 17S, if not switched to the power saving mode, the first level signal Level 1 and the second level signal Level 2 are normally output so that all the circuits are turned on through the video circuit unit 4. (18S)

That is, in the normal state, all power including the cathode heater of the CRT is supplied and a negative voltage (-V) is supplied to the grid electrode of the CRT.

On the other hand, in the determination result 17S, when the power saving mode is switched to the normal mode, as shown in Figure 4, the cut off voltage (Cut Off Voltage) is maintained at 0V for a predetermined time, so that the grid voltage is applied to + V voltage Control to ensure maximum release of hot electrons (19S).

As such, when reactivating from the power saving mode to the normal mode, the time for reactivation may be within 5 seconds if the hot electrons are emitted as much as possible. At this time, the time for maintaining the cut-off voltage at 0V and the grid voltage at + V is sufficient to be about 2 seconds or less, depending on the CRT.

The above process is repeated when the main power is not cut (16S).

In FIG. 3, the power saving mode is described only by monitoring the synchronization signal. However, the power saving mode is not limited thereto, and color signals R, G, and B input from the PC may be determined to determine the normal mode or the power saving mode. In addition, it is possible to execute the two-stage power saving control method according to the present invention by using the voltage change inside the monitor.

The monitor power saving control method according to the present invention as described above has the following advantages.

First, although the power consumption of the monitor is controlled in three stages of the normal mode, the standby mode, and the off mode, in the present invention, the power consumption of the monitor is controlled in two stages of the normal mode and the power saving mode. Can be reduced.

That is, the cathode heater power is supplied in the standby mode in which one synchronization signal of the vertical or horizontal synchronization signal is input. However, in the present invention, the heater power is cut off even when the synchronization signal of the vertical or horizontal synchronization signal is input. The power consumption is further reduced.

Secondly, the reactivation time of about 8 seconds is required when reactivating from the off mode to the normal mode. However, in the present invention, the cut-off voltage is maintained at 0V for a predetermined time, and the grid voltage is maintained at + V, thereby reactivating the CRT by maximizing hot electron emission. Thus, the reactivation time within 5 seconds is reactivated in the conventional standby mode. Has

Claims (7)

Determining a normal mode or a power saving mode; Supplying power to all circuits when it is determined that the operation mode is normal; Displaying a warning message to enter the power saving mode when determined to be a power saving mode, and waiting for a predetermined time to turn off all power circuits selectively operated by the power control means as well as the cathode heater power when a user key input is not detected. Power control method of the monitor, characterized in that configured. The method of claim 1, When switching from the power saving mode to the normal mode, the monitor further comprises the step of maintaining the cut-off voltage at a voltage of 0V for a period of time, the grid voltage to + V voltage to maximize the release of hot electrons Control method. The method of claim 2, The time for maintaining the cut-off voltage at 0V and the grid voltage at + V is within 2 seconds. The method of claim 1, The normal or power saving mode is determined as a normal mode when the vertical and horizontal synchronization signals input from the PC are normally supplied, and is determined as a power saving mode when at least one of the two synchronization signals is abnormally input. Power control method of the monitor, characterized in that. The method of claim 1, The method of determining the normal or power saving mode is determined by using a change in the color signal input from the PC. The method of claim 1, The method of determining the normal or power saving mode of the power control method of the monitor, characterized in that the determination using the power change inside the monitor. The method of claim 1, And displaying the warning message further comprises displaying a waiting time count state for entering a power saving mode.