KR200145519Y1 - Led indicator driving citcuit in dpms circuit - Google Patents

Abstract

The present invention relates to a driving circuit device of an LED display unit in a DPMS circuit, and more particularly, to an LED driving circuit device of a DPMS circuit for displaying a power saving mode by using a transistor. Switching by a voltage output terminal which is controlled by an output monitor off signal or a computer main body off signal and which is an output terminal of an auxiliary voltage for driving a driving voltage and a wake detection unit to the monitor and the computer main body, and a power saving mode signal output from the voltage output terminal A display device control unit for displaying an operation and a light emitting diode (LED) display unit which is controlled according to a control signal output from the display unit control unit and the voltage output terminal, the monitor integrated computer directly recognizes the power saving mode signal, the light emitting diode (LED) ) To drive the driving circuit of the display device Therefore, the driving circuit of the light emitting diode (LED) display device can be simply configured to reduce the production process of the monitor integrated computer.

Description

Driving circuit of the LED display unit in the DPM circuit

1 is a driving circuit diagram of a light emitting diode display in a conventional DPM circuit.

2 is a power saving circuit diagram of a monitor integrated computer to which the driving circuit of the LED display unit according to the present invention is applied.

3 is a driving circuit of the LED display unit in the DMP circuit according to the present invention.

The present invention relates to a driving circuit of a light emitting diode display unit in a DPM circuit, and more particularly, to a driving circuit of a light emitting diode display unit in a DPM circuit displaying a power saving mode using a transistor.

In general, the conventional power saving circuit adjusts various functions using a microcomputer to perform a user's convenience and power saving function according to the diversification of the monitor technology. Accordingly, the presence or absence of a synchronization signal is determined according to data stored in a microcomputer and an input program by a power saving function that performs a power saving function. Next, the DPM mode (Display Power Management Signaling Mode) is operated according to the signal output from the microcomputer.

A state in which the horizontal synchronization signal is turned off in the DPM mode is called a standby mode. When the standby mode is executed, the video signal is cut off and no video signal is output from the monitor. On the other hand, when the vertical synchronization signal is off, the deflection voltage is cut off. On the other hand, when both the horizontal and vertical synchronization signals are turned off, the secondary power supply of the transformer is cut off by using a pulse width modulation circuit. This reduces the power consumed by the monitor.

A conventional display device for displaying each operation mode in such a general DMP circuit to a user will be described with reference to the accompanying drawings.

1 is a light emitting diode driving circuit for driving a light emitting diode in a conventional DMP circuit. The LED driving circuit detects vertical and horizontal synchronous signals generated from a video card (not shown in the drawing) of the computer main body and determines whether the vertical and horizontal synchronous signals are generated. A switch unit 200 that receives the horizontal and vertical synchronization signals output from the computer 100 and performs a switching operation, and a standby mode and a suspend mode according to the switching signals output from the switch unit 200. And a light emitting diode display unit 300 for displaying (Suspend Mode) and Off Mode.

The state in which the monitor is turned off and the computer body is turned on is called a standby mode.

The state in which both the monitor and the computer body are turned off is called suspend mode.

The state in which the monitor, the computer body, and the light emitting diodes are all turned off is called off mode.

Next, the operation of the light emitting diode driving circuit will be described.

Data processed by a central processing unit (not shown) of the computer main body is output to a monitor through a video signal generator called a video card. The horizontal and vertical synchronization signals generated from the video card are input to the microcomputer 100. Next, the microcomputer 100 determines whether horizontal and vertical synchronization signals have been generated from the video card. Subsequently, when the microcomputer 100 determines that the current operation mode is a standby mode, a high level switching signal is output from the microcomputer 100. Next, a high signal is input to the switch unit 200 through the resistor R1, and the transistor Q1 is turned on. When the transistor Q1 is turned on, the light emitting diode LED1 of the light emitting diode display 300 is turned on by the driving voltage B + 2. Then, the light emitting diode LED1 is displayed in green, and the user confirms that the current operation mode is the standby mode.

On the other hand, when the microcomputer 100 determines that the current operation mode is the suspend mode, a low level switching signal is output from the microcomputer 100.

Next, the transistor Q1 is turned off. Then, a current flows from the driving voltage B + 1 of the switch unit 200 in the direction of the diode D1, the resistor R2, the light emitting diode LED2, the resistor R3, and the ground terminal, so that the light emitting diode ( LED2) turns on. Then, the light emitting diode LED2 is displayed in red, and the user confirms that the current operation mode is the suspend mode.

In general, the driving circuit of the LED display unit which is widely used has a microcomputer to detect horizontal and vertical synchronization signals, and the LEDs of the LED display unit are used for each mode, so the unit price of the product is high and the circuit is complicated. There was this.

Therefore, the present invention has been made to solve the above problems, and an object of the present invention is to provide a driving circuit of a light emitting diode display in a DPS circuit which can reduce the unit cost of a product and can easily configure a circuit.

In order to achieve the above object, the driving circuit of the LED display unit according to the present invention includes a switching unit for performing a switching operation by receiving a monitor off signal and a computer body off signal output from a wake-up detector, and switching of the switching unit. The light emitting diode display is configured to display the normal mode, the standby mode, the suspend mode, and the off mode, which are operating states of the computer main body and the monitor, in different colors, and the light emitting diode display is output from the wakeup detection unit. A light emitting diode (LED4) indicating the normal mode, which is a mode in which the computer main body and the monitor operate in a normal state by receiving a high level computer body off signal, and a low level monitor off signal from the wakeup detector is Auxiliary when output to switching unit The power supply voltage output from the power supply is received through the switching unit to emit red light to display a suspend mode in which both the monitor and the computer main body are turned off, and a low level monitor off signal is output from the wakeup detection unit to the switching unit. When the low level computer body off signal is output from the wake-up detector to the light emitting diode LED4, the monitor emits light simultaneously with the light emitting diode LED4 to display an amber color. In standby mode. When the power supply voltage is not supplied to the computer main body from an external AC power source, the wake-up detection unit receives a low level computer main body off signal, and the auxiliary power supply does not receive a driving voltage through the switching unit so that the light emitting diode LED 4 ) And a light emitting diode (LED5) indicating an off mode in which no power voltage is supplied to the computer main body and the monitor from external AC power.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a power saving circuit diagram of a monitor-integrated computer to which the driving circuit of the LED display unit is applied in the DPM circuit.

As shown in FIG. 2, the power saving circuit of the monitor-integrated computer includes a monitor power control unit 15 that outputs a control signal to control the power of the monitor by receiving a monitor off signal generated from a wake-up detection unit (not shown); A first Pulse Width Modulation Integrated Circuit (hereinafter referred to as PWM IC) 30 that receives a control signal output from the monitor power controller 15 and outputs a square wave voltage having a pulse width; A first transformer 35 for transforming the voltage output from the PWM IC 30, a monitor driving voltage output terminal 41 for outputting the monitor driving voltage output from the first transformer 35 to the monitor, and the wake-up; A second PWM IC 50 for receiving a control signal to control the power supply of the computer body by receiving the computer body off signal output from the detection unit and outputting a square wave voltage having a pulse width; The computer main body driving voltage output stage for outputting the computer main body driving voltage output from the second transformer 55 and the second transformer 55 for receiving the square wave voltage output from the 2 PWM IC 50 and transforming the square wave voltage ( 42).

3 is a driving circuit of a light emitting diode display of a DPS circuit according to the present invention, wherein the driving circuit of the light emitting diode display is configured to receive a monitor off signal and a computer main body off signal output from a wake-up detector (not shown). And a light emitting diode display unit 70 for displaying the normal mode, the standby mode, the suspend mode, and the off mode, which are operating states of the computer main body and the monitor, in different colors by the switching operation of the switching unit. Consists of

The switching unit 60 monitors the monitor off signal and the computer main unit off signal output from the wake-up detection unit, the monitor power control unit 15, the first PWM IC 30, the first transformer 35, and the monitor driving voltage output terminal ( 41, a resistor Q16 connected between the auxiliary power supply and the base of the transistor Q8 to supply a power supply voltage of the auxiliary power supply to the base of the transistor Q8 and to switch the transistor Q8. It consists of a resistor R17 connected between the emitter of transistor Q8 and the ground terminal to maintain the potential of the emitter of transistor Q8.

An auxiliary power supply is connected to the switching unit 60 so as to supply a power supply voltage necessary for driving the switching unit 60.

The LED display unit 70 receives a high level computer body off signal output from the wake-up detection unit and emits green light to display a normal mode which is a mode in which the computer body and the monitor operate in a normal state. When the low level monitor off signal is output from the wakeup detector to the switching unit 60, the monitor and the computer main body receive the power voltage output from the auxiliary power source through the switching unit 60 and emit light in red. And display the suspend mode in which all are off, and a low level monitor off signal is output from the wakeup detector to the switching unit 60, and a low level computer body off signal is output from the wakeup detector. When outputted to LED4, it simultaneously emits light with the light emitting diode LED4 to display an amber color. Therefore, the monitor is turned off and displays a standby mode in which the computer main body is operated. When the power supply voltage is not supplied to the computer main body from an external AC power source, the wake-up detection unit receives a low level computer main body off signal. The driving mode is not supplied from the auxiliary power supply through the switching unit 60 and thus does not emit light together with the light emitting diode LED4, thereby displaying an off mode in which the power supply voltage is not supplied to the computer main body and the monitor from an external AC power supply. It consists of a light emitting diode (LED5).

The operation of the power saving circuit of the monitor-integrated computer shown in FIG. 2 will be described.

The wake-up detection unit detects a key signal through a keyboard or a fax / communication modem signal and a sound signal (not shown) generated by a sound card in the computer main body. The wake-up detector generates a monitor off signal and a low level computer main body off signal if a key signal of a keyboard, a modem signal of a fax / communication modem, and a sound signal of a sound card are not generated.

The low level monitor off signal generated from the wakeup detector is input to the base of the transistor Q2 of the monitor power supply controller 15. Transistor Q2 is then turned off. The potential of the collector of transistor Q2 is divided by resistors R7 and R8 and then smoothed through capacitor C1 and input to the base of transistor Q3. Transistor Q3 is then turned on.

Next, the light emitting diode LED2 of the photo coupler OP1 is turned on. When the light emitting diode LED2 is turned on to emit light, the emitted light is input to the base of the photo transistor PTr1 to turn on the photo transistor PTr1. When the photo transistor PTr1 is turned on, the potential of the cathode of the diode D2 becomes very low.

Transistor Q4 is then turned off. When the transistor Q4 is turned off, the first PWM IC 300 is turned off. When the first PWM IC 30 is turned off, a low level voltage is output from the first PWM IC 30.

Subsequently, the monitor driving voltage is not output from the first transformer 35 to the monitor. This turns off the monitor.

On the other hand, when the low level monitor off signal is not generated from the wakeup detector, the monitor power supply controller 15 outputs a high level control signal to the first PWM IC 30.

Next, the first PWM IC 30 is turned on.

Subsequently, a square wave voltage having a pulse width is output from the first PWM IC 30. Next, the voltage transformed from the first transformer 35 is supplied to the monitor through the monitor driving voltage output terminal 41. Next, the monitor is turned on.

In addition, the computer body off signal generated from the wake-up detection unit is input to the base of the transistor Q5 of the computer body power supply control unit 45. Transistor Q5 is then turned off. The potential of the collector of transistor Q5 is then divided by resistors R13 and R14 and then smoothed through capacitor C2 and input to the base of transistor Q6.

Transistor Q6 is then turned on.

Next, the light emitting diode LED3 of the photo coupler OP2 is turned on. When the light emitting diode LED3 is turned on to emit light, the emitted light is input to the base of the photo transistor PTr2 to turn on the photo transistor PTr2. When the photo transistor PTr2 is turned on, the potential of the cathode of the diode D3 becomes very low. Transistor Q7 is then turned off. When the transistor Q7 is turned off, the second PWM IC 50 is turned off. When the second PWM IC 50 is turned off, the second PWM IC 50 outputs a low level voltage.

Subsequently, the computer main body driving voltage is not output from the second transformer 55 to the computer main body. The computer body is then turned off.

On the other hand, if the low level computer main unit off signal does not occur from the wakeup detector, the computer main unit power supply control unit 45 outputs a high level control signal. Then, the second PWM IC 50 is turned on. Subsequently, a square wave voltage having a pulse width is output from the second PWM IC 50.

Next, the voltage transformed from the second transformer 55 is supplied to the computer body through the computer body drive voltage output terminal 42. Next, the computer body is turned on.

Next, the operation of the driving circuit of the LED display unit in the DMP circuit shown in FIG. 3 will be described.

In order to reduce the power consumed by the computer, the monitor-integrated computer in which the DPM circuit is incorporated may execute a power saving mode according to the wakeup signal detected by the wakeup detector. In the power saving mode performed by the wake-up signal, the state in which the monitor and the main body of the computer are turned on is called a normal mode, and the state in which the monitor is turned off and the main body of the computer is in a standby mode is called a standby mode. And the state in which the computer main body is turned off is called a suspend mode. The power saving mode is switched from the normal mode to the standby mode, and the standby mode is switched to the suspend mode, thereby reducing power consumption of the monitor-integrated computer.

Therefore, the driving circuit of the LED display unit in order of each power saving mode is as follows.

In the normal mode, a wake-up signal is detected and the monitor and the computer main body are turned on, and a high signal is output through the computer main body driving voltage output terminal 42 and the monitor driving voltage output terminal 41. The high signal output from the monitor driving constant voltage output terminal 41 is input to the base of the transistor Q8 of the switching unit 60. The transistor Q8 is turned off by the high signal inputted to the base to fail to turn on the light emitting diode LED5 of the light emitting diode display unit 70.

On the other hand, the high signal output from the computer main body driving voltage output terminal 42 turns on the light emitting diode LED4 through the resistor R18 of the light emitting diode display unit 70.

Therefore, in the normal mode, the light emitting diode LED4 is turned on and is displayed. In this case, when the light emitting diode is green, the user sees that the green light is displayed on the light emitting diode display 70 and the normal mode is operated. Will be recognized.

When the monitor off signal is detected by the wake up detector in the computer operating in the normal mode, the driving voltage supplied to the monitor is cut off by the monitor off signal. Then, a low signal is output through the monitor driving voltage output terminal 41. The low signal output through the monitor driving voltage output terminal 41 is input to the base of the transistor Q8 of the controller 60.

Transistor Q8 is turned on by the input low signal. When the transistor Q8 is turned on, a current flowing through the auxiliary voltage output terminal flows through the transistor Q8 to turn on the light emitting diode LED5. At this time, if the light emitting diode LED5 is red, the red color is displayed through the light emitting diode display. In addition, the high signal output through the computer main driving voltage output terminal 42 is also turned on through the resistor R18 of the LED display unit 70.

Therefore, in the standby mode, the light emitting diodes LED4 and LED5 are turned on, so that green and red are mixed, thereby emitting light of amber (Amber color). When amber (Amber color) is displayed through the light emitting diode display unit 70, the user recognizes that the standby mode is currently operated in the monitor integrated computer.

If the wake-up signal is not detected again for a predetermined period of time in the monitor-integrated computer operating in the standby mode, the computer main body is turned off by cutting off the power supplied to the computer main body. The low signal is then output through the computer main drive voltage output terminal 42. The light emitting diode LED4 of the light emitting diode display unit 70 is turned off by the low signal output from the main body driving voltage output terminal 42.

At the same time, a low signal is output through the monitor driving voltage output terminal 41. The transistor Q8 of the control unit 60 is turned on by the low signal input through the monitor driving voltage output terminal 41. When the transistor Q8 is turned on, a current flowing through the auxiliary voltage output terminal 43 turns on the light emitting diode LED5 of the light emitting diode display unit 70 through the transistor Q8. When the light emitting diode LED5 is turned on, a red color is displayed through the light emitting diode display 70 so that the user recognizes that the monitor-integrated computer is operated in the suspend mode.

At this time, since the auxiliary voltage flowing through the auxiliary voltage output terminal 43 is used as a driving voltage of the wake-up detection unit, the suspend mode is operated in the monitor-integrated computer so that the monitor and the computer main body are not cut off even when the power is turned off. .

Looking at Table 1 for the operation state of the LED display unit 70 is shown as follows.

As shown in Table 1, in the normal mode, the monitor off signal is displayed in green on the light emitting diode display unit 70 when the high signal is inputted to the computer main body off signal. In the standby mode, the monitor off signal is a low signal and the computer body off signal is a high signal. The light emitting diode display unit 70 displays a amber mixed green and red color.

In the suspend mode, a monitor off signal and a computer main unit off mode low signal are inputted while the monitor and the main body of the computer are turned off, and the red light is displayed on the LED display unit 70, and the off mode is the main unit of the monitor and the main body of the computer. And the light emitting diode display unit 70 are all turned off.

Therefore, the present invention enables the driver integrated circuit of the LED display device to be driven by directly recognizing the power saving mode signal in the monitor integrated computer, thereby reducing the production process of the monitor integrated computer. have.

In addition, by not using a microcomputer in the driving circuit of the LED display unit, there is a very excellent effect that can lower the cost of the product.

Claims (3)

A switching unit configured to receive a monitor off signal and a computer main unit off signal output from the wake-up detection unit, and to perform a switching operation; a normal mode, a standby mode, a suspend mode, which are operating states of the computer main body and the monitor by the switching operation of the switching unit; The LED display unit is configured to display the OFF mode in a different color. The LED display unit receives a high level computer body off signal output from the wake-up detector and emits green light, thereby operating the computer body and the monitor in a normal state. The light emitting diode (LED4) indicating the normal mode that is the mode to be turned on, and when the low level monitor off signal from the wake-up detection unit is output to the switching unit receives the power supply voltage output from the auxiliary power supply through the switching unit to emit red light Monitor and computer body A suspend mode in which all are off is displayed, and a low level monitor off signal is output from the wakeup detector to the switching unit, and a low level computer main unit off signal is output from the wakeup detector to the light emitting diode LED4. And outputs the same color as the light emitting diode LED4 to display an amber color to display a standby mode in which the monitor is turned off and the computer main body is operated. When the power supply voltage is not supplied to the computer main body from an external AC power source, the wake-up detection unit receives a low level computer main body off signal, and the auxiliary power supply does not receive a driving voltage through the switching unit so that the light emitting diode LED 4 Drive light emitting diode (LED5) for displaying an off mode in which no power voltage is supplied to the computer main body and the monitor from external AC power. in. The driving circuit of claim 1, wherein an auxiliary power supply is connected to the switching unit to supply a power supply voltage for driving the switching unit. The transistor of claim 1, wherein the switching unit receives a monitor off signal and a computer main unit off signal output from the wakeup detector, and supplies a power supply voltage of an auxiliary power supply to a base of the transistor Q8. The resistor R16 connected between the auxiliary power supply and the base of the transistor Q8 and the resistor connected between the emitter of the transistor Q8 and the ground terminal to maintain the potential of the emitter of the transistor Q8. R17), the driving circuit of the LED display unit in the DMP circuit.