KR19980036413A - DPMS control system - Google Patents

Abstract

The present invention relates to a DPMS mode device. More particularly, the present invention relates to a DPMS mode device, and more specifically, to a DPMS mode by sensing a voltage applied to a specific pin of a video card connected between a video card embedded in a computer and a display device to transfer a video signal and a synchronization signal. A DPMS control system that can be implemented.

A signal cable for transmitting video signals and synchronization signals to a display device from a video card embedded in a computer, and a DPMS control signal provided by sensing a voltage applied to a specific pin of the signal cable provided at a display device side end of the signal cable. And a voltage sensing unit for outputting a video signal and a DPMS control circuit connected to the voltage sensing unit to control a DPMS mode according to the control signal of the voltage sensing unit. By sensing the voltage applied to a specific pin of the video card that delivers the synchronization signal, an analog DPMS control system can be realized using a digital DPMS driving circuit using a microcomputer.

Description

DPMS control system

The present invention relates to a DPMS mode device. More particularly, the present invention relates to a DPMS mode device, and more specifically, to a DPMS mode by sensing a voltage applied to a specific pin of a video card connected between a video card embedded in a computer and a display device to transfer a video signal and a synchronization signal. A DPMS control system that can be implemented.

Generally, computer peripheral devices refer to various input and output devices such as monitors, printers, and plotters connected to a computer system. Typically, such computer peripheral devices are powered by a computer at the same time, depending on the type of the difference, and may be supplied to these devices, or may be supplied by a separate power on / off switch.

Although each device has its own characteristics, each peripheral device has to go through initialization and preheating operation when the power is applied. Therefore, it is impossible to use these devices immediately after the voltage is applied. If not, they have been kept powered up without shutting off the power.

In particular, a monitor widely used as a display device of a computer is a device that receives an input signal from a computer and converts it into an image signal so that the user can visually check the operation of the computer. Is also determined.

In other words, when combined with a computer, a signal transmission cable is used to operate by receiving a signal from the computer. When there is no signal from the computer, the basic operation is lost, but the purpose of the device loses its meaning.

A common way to control this is to blank the data image that was being displayed on the monitor if the computer user did not use the computer for more than the set time. If the user inputs a key again while the screen blanking function is being performed, the blanking function of the computer monitor is released to redisplay the previously displayed data image.

This method blanks only the data image being displayed on the monitor, so that the monitor is still powered during the blanking period, so that the power consumption is about the same as in normal operation.

As a solution to this, the Video Electronics Standards Association (VESA) proposes a Display Power Management System (DPMS) that can save power by managing the power of a monitor, which is a computer peripheral, in response to the usage of the computer system.

According to the DPMS mode, the vertical synchronization signal of the horizontal synchronization signal is selectively supplied to or disconnected from the computer in order to realize different power management states in response to the use state of the computer system. Performs a power management state corresponding to the input state.

The power management states are divided into ON, STAND-BY, SUSPEND, and OFF states, and the horizontal and vertical synchronization signals are supplied according to each power management state. The state is shown as Table 1 below.

Power Management Status Synchronous signal Horizontal Perpendicular ON state U U STAND-BY STATE radish U Suspend status U radish OFF state radish radish

That is, in the on state, both pulse outputs of the horizontal synchronizing signal and the vertical synchronizing signal exist, and in the standby state, only the pulse output of the vertical synchronizing signal appears, and in the pause state, only the pulse output of the horizontal synchronizing signal appears. The pulse outputs of both the vertical and horizontal sync signals do not appear.

Therefore, the power management states can be distinguished according to the pulse output states of these horizontal synchronizing signals and the vertical synchronizing signals, and these power management states are gradually turned on in response to the continuous passage of time when the computer system is not used. Switch from standby status to pause status to off status.

In the above table (1), the absence (none) and presence (state) of each signal means the presence or absence of the normal synchronization signal frequency of each signal, the presence (state) indicates that the horizontal synchronization signal is more than 10 Hz When the vertical synchronization signal is 40 Hz or more.

At this time, the duty rate of the vertical and horizontal pulses should be less than 25%.

In this way, a monitor connected to a computer and displaying various information saves power consumption by operating in a power saving mode by DPMS when the user does not use the computer.

This DPMS mode implementation proceeds as shown in FIG. 1.

The microcomputer 20 controls whether the DPMS mode is implemented according to the presence of the horizontal synchronizing signal H_SYNC and the vertical synchronizing signal V_SYNC transmitted from the computer 10, and pulses according to the control signal of the microcomputer 20. PWM-IC 30 for adjusting the duty and SMPS 40 for controlling the on / off of the power provided to the secondary side according to the switching result of the PWM-IC (30) to save power in the normal display state ( During the transition to the DPMS mode, PWM control is performed to implement the off mode.

At this time, a method of reducing power by forcibly lowering the duty of the pulse to lower the secondary output voltage of the SMPS is used.

However, such a conventional DPMS implementation method should continuously check the horizontal synchronizing signal H_SYNC and the vertical synchronizing signal V_SYNC transmitted from the computer 10 to the microcomputer 20, and requires a display device of high resolution. In order to meet the expectations, the frequency of the horizontal and vertical synchronization signals is gradually increased, and there is a problem in that the setting of the reference bandwidth for implementing the DPMS mode is set in advance in the microcomputer 200.

The present invention is to solve this problem, it is possible to implement the DPMS mode by sensing the voltage applied to a specific pin of the video card which is connected between the video card and the display device embedded in the computer to transfer the video signal and the synchronization signal The purpose is to provide a DPMS control system.

In order to achieve the above object, the present invention provides a signal cable for transmitting a video signal and a synchronization signal to a display device from a video card embedded in a computer,

A voltage sensing unit installed at a display device side end of the signal cable to sense a voltage applied to a specific pin of the signal cable and output a DPMS control signal;

A normal mode control circuit connected to the voltage sensing unit to adjust the display device to operate normally when the control signal of the voltage sensing unit is in a normal mode, and a control signal of the voltage sensing unit to be in a standby mode connected to the voltage sensing unit. A standby mode control circuit for controlling the display device to operate in a standby mode, and a pause mode control connected to the voltage sensing unit to adjust the display device to be paused when the control signal of the voltage sensing unit is in the pause mode And an off mode control circuit connected to the voltage sensing unit and configured to turn off the display apparatus when the control signal of the voltage sensing unit is in the off mode.

1 is a configuration diagram of a DPMS mode operation system according to the prior art;

2 is a configuration diagram of a DPMS operation system according to an embodiment of the present invention;

FIG. 3 is a block diagram illustrating FIG. 2 in more detail.

4 is a circuit diagram illustrating in detail the voltage sensing unit of FIG. 2.

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings. FIG. 2 shows installation of a cable for signal transmission between a computer and a display device, and a video card 11 is incorporated into the computer 10. The signal cable 200 for transmitting the video signal and the synchronization signal transmitted from the video card 11 to the voltage sensing unit 110 in the monitor 100 is provided.

3 illustrates that a plurality of control circuits for implementing a DPMS mode are connected to a rear end of the voltage sensing unit 110 of FIG. 2. Standby mode control circuit 111 that operates when the sensing result of the voltage sensing unit 110 is in the standby mode, and pause mode operation that is operated when the sensing result of the voltage sensing unit 110 is in the pause mode. It has been shown that the circuit 112 and the off-mode control circuit 113 that operates when the sensing result of the voltage sensing unit 110 in the off mode.

4 is a detailed circuit diagram of the voltage sensing unit 110. Resistor (R1, R2, R3) for detecting the voltage applied to a specific pin of the signal cable 200, and a differential amplifier receiving the voltage received through the resistor (R1, R2, R3) to each non-inverting terminal (OP1, OP2, OP3), the standby mode control circuit 111 connected to each output terminal of the differential amplifiers OP1, OP2, OP3, the suspend mode control circuit 112, and the off mode control circuit 113. It is configured to include.

The voltage applied through the specific pin of the signal cable 200 is transferred to the resistors R1, R2, and R3. The voltage applied to the resistor R1 is transmitted to the non-inverting terminal of the differential amplifier OP1, and the reference voltage V _ref1 is applied to the inverting terminal of the differential amplifier OP1, so that the differential amplifier ( The output voltage of OP1) is determined. At this time, whether to drive the DPMS mode control circuit at the next stage is determined by the output voltage. For example, when the voltage transmitted from the video card 11 in the computer 10 to the voltage sensing unit 110 through a specific pin of the signal cable 200 is 0V, 1V, 3V, 5V, the DPMS mode is the normal mode. Let's say you run in standby, suspend, or off mode. If the reference voltages V _REF1, V _{REF2, and} V _REF3 applied to the inverting terminals of the respective differential amplifiers OP1, OP2, and OP3 are 1 V, 3 V, and 5 V, respectively, the DPMS mode is not implemented in the normal mode. If there is no seating of the user of the computer 10 or the keyboard is not used for a certain period of time, if 1 V, i.e., a standby mode signal is transmitted according to the DPMS mode, the difference between the reference voltage V _REF1 of the differential amplifier OP1 When the standby mode control circuit 111 operates and a 3V signal is transmitted, the suspend mode control circuit operates by a difference from the reference voltage V _REF2 of the differential amplifier OP2, and a voltage of 5V is transmitted. In this case, the off-mode control circuit operates according to the output signal of the differential amplifier OP3, thereby implementing DPMS.

As described above, the present invention provides a digital DPMS driving circuit using a microcomputer by sensing a voltage applied to a specific pin of a video card connected between a video card embedded in a computer and a display device and transmitting a video signal and a synchronization signal. This has the effect of implementing an analog DPMS control system.

Claims (3)

Signal cables for transmitting video and sync signals from the video card built into the computer to the display device; A voltage sensing unit installed at a display device side end of the signal cable to sense a voltage applied to a specific pin of the signal cable and output a DPMS control signal; A standby mode adjustment circuit connected to the voltage sensing unit to adjust the display device to operate in the standby mode when the control signal of the voltage sensing unit is in the standby mode; A pause mode control circuit connected to the voltage sensing unit and configured to pause the display apparatus when the control signal of the voltage sensing unit is in a pause mode; And an off-mode adjusting circuit connected to the voltage sensing unit to adjust the display device to be turned off when the control signal of the voltage sensing unit is in an off mode. The method of claim 1, The voltage sensing unit comprises a plurality of differential amplifiers that can determine whether the DPMS mode operation by comparing the voltage applied to a specific pin of the signal cable with a reference voltage. The method of claim 2, The differential amplifier is configured to receive a voltage transmitted through a specific pin of the signal cable to the non-inverting terminal, and to apply a reference voltage to the inverting terminal to differentially amplify to display a DPMS control signal at the output terminal .