KR19980015196A - METHOD AND CIRCUIT PROTECTING MICROCOMPUTER - Google Patents

Abstract

The present invention relates to a microcomputer protection circuit and a method thereof, and more particularly, to a microcomputer protection circuit and a microcomputer which are provided with a key operation unit for outputting a key signal when an operation is performed to reduce a malfunction caused by heat generated in a monitor, (H-SYNC) and a vertical synchronizing signal (V-SYNC) output from a video card, receives a key signal output from the key operation unit, A microcomputer for receiving a temperature signal output from the sensor unit and outputting a power off signal by judging an applied monitor temperature signal and a power supply circuit for receiving a power off signal output from the microcomputer and interrupting power consumed in the monitor, , Receives information data on the temperature signal output from the microcomputer, and performs OSD processing This has the effect of configuring the OSD and outputting the OSD signal to cause the microcomputer prevents the heat generated in the monitor malfunction is severe, degradation occurs.

Description

METHOD AND CIRCUIT FOR PROTECTING MICROCOMPUTER

The present invention relates to a microcomputer protection circuit and method, and more particularly, to a microcomputer protection circuit and a method thereof, in which a temperature inside the monitor and a temperature around the monitor are measured using a temperature sensor and a measured temperature is compared, thereby preventing malfunction And more particularly, to a microcomputer protection circuit and method.

Generally, integrated circuits are sensitive to heat, and this heat can cause malfunctions and even worse, deterioration of the integrated circuit during operation. As such, integrated circuit manufacturers are making a lot of effort for heat dissipation techniques to release the heat generated during operation of the integrated circuit to the outside of the integrated circuit.

Among such integrated circuits, microcomputers are more rapid and miniaturized due to the development of integrated circuit manufacturing technology, and tend to generate more heat during operation. The heat-emitting material and the cooling fan are used to release the generated heat.

An internal circuit of a conventional monitor having such a microcomputer will be described with reference to the accompanying drawings.

1 is a block diagram showing an internal circuit of a conventional monitor which is generally used. As shown in the figure, a personal computer (PC) 100 includes a CPU 110 for receiving and processing keyboard signals used by a user and generating data according to a processed result, G and B for synchronizing the processed video signals R, G, and B with the video signals R, G, and B by processing the video signals R, And a video card 120 for outputting a vertical synchronizing signal (V-SYNC) and a vertical synchronizing signal (V-SYNC).

The monitor 200 receiving the video signals R, G and B and the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 120 in the PC 100 A microcomputer 210 for receiving a horizontal synchronization signal H-SYNC and a vertical synchronization signal V-SYNC, a control button for generating a screen control signal for controlling the monitor screen and outputting the generated monitor screen control signal A horizontal and vertical output circuit 230 for synchronizing a raster with a monitor screen control signal output from the microcomputer 210 and a reference oscillation signal; A power circuit unit 240 for supplying a driving voltage to the microcomputer 210, the horizontal and vertical output circuit units 230 and the video signal processing unit 240; 250).

Each block in the monitor 200 having such a structure will be described in more detail as follows.

The microcomputer 210 receives the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC output from the video card 120. The microcomputer 210 receiving the horizontal synchronization signal H-SYNC and the vertical synchronization signal V-SYNC incorporates various monitor screen control data. When the monitor screen control signal is applied to the microcomputer 210 by the control button unit 220, the microcomputer 210 outputs an upper adjustment signal for adjusting the image displayed on the monitor screen according to the applied screen control signal .

The control button unit 220 outputs horizontal and vertical position control signals, horizontal and vertical size adjustment signals, and the like. The microcomputer 210 receiving the monitor screen control signal outputs a phase adjustment signal and a reference oscillation signal according to the monitor screen control signal applied thereto. The reference oscillation signal outputted from the microcomputer 210 is applied to the horizontal and vertical oscillation signal processor 230-1 in the horizontal and vertical output circuit unit 230. [ In addition, the horizontal and vertical oscillation signal processor 230-1 receives horizontal and vertical oscillation signals applied from horizontal and vertical oscillation circuits (not shown).

The horizontal and vertical oscillation signal processor 230-1 receiving the horizontal and vertical oscillation signals generates a sawtooth wave based on the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC applied from the video card 110, The switching speed of the on / The vertical pulse output from the horizontal and vertical oscillation signal processor 230-1 is applied to the vertical drive circuit 230-2. The vertical drive circuit 230-2, which receives the vertical oscillation signal, generally uses one stage of the vertical amplification type. The emitter follower 230-2 applies an input to the base terminal of the transistor and extracts an output voltage from the emitter terminal. The mold is used a lot. Therefore, the linearity improving operation is performed rather than the gain. The vertical output circuit 230-3 receiving the current signal output from the vertical drive circuit 230-2 generates a sawtooth current corresponding to the vertical synchronization pulse flowing through the V-DY 230-4, The vertical scanning period is determined.

In addition, the horizontal drive circuit 230-5 receives the horizontal oscillation signal output from the horizontal and vertical oscillation signal processor 230-1. The horizontal drive circuit 230-5 supplies the horizontal oscillation signal with sufficient current to turn on / off the horizontal output circuit 230-6. The horizontal drive circuit 230-6 is an in-phase (polarity) type in which the output stage is turned on when the drive stage is on, and a reverse phase (reverse polarity) mode in which the output stage is also off when the drive stage is currently in use have. The horizontal output circuit 230-6 receiving the current output from the horizontal drive circuit 230-5 generates a sawtooth current in the H-DY 230-7. The horizontal scanning period is determined by the sawtooth current.

A flyback transformer (hereinafter referred to as FBT) 230-9 is connected to the anode terminal 240-4-1 of the CRT 240-4 to supply a stable direct current (DC) voltage to the anode terminal 240-4-1 of the CRT 240-4. A large high voltage is generated even when the collector pulse is small, and a cathode ray tube (hereinafter referred to as a CRT) 240-8 is generated by using a leakage collector and a harmonic caused by the distribution inductance of the high- 3 to the anode terminal 240-3-1.

The process of displaying the image signal on the CRT 240-4 in the image signal processing unit 240 receiving the high voltage through the anode terminal 240-4-1 will be described below. The OSD unit 240-1 receiving the OSD gain signal generated by the screen control through the microcomputer 210 generates and outputs the OSD gain signal.

The video preamplifier 240-2, which receives the OSD gain signal output from the OSD unit 240-1 and the video signals R, G, and B applied from the video card 120, (R, G, B) are amplified to maintain a constant voltage level. For instance, for example to amplify a signal of less than 1V _PP into a signal of 4 ~ 6V _PP. Thus, the video output amplifier that amplifies a signal of 4 ~ 6V _PP (240-3) will supply the energy in each pixel to amplify a signal of 40 ~ 60V _PP. The video signal amplified by the video output amplifier 240-3 is applied to the cathode of the CRT 240-4 and the video signals R, G, and B are displayed on the monitor screen.

The power supply circuit unit 250 for supplying the driving voltage for displaying the video signals R, G, and B through the monitor screen includes an alternating current (AC) input terminal 250-1 ). The degaussing coil 250-2 receiving the AC output through the AC input terminal 250-1 can recover the color blurring state caused by the color purity of the monitor screen or the external condition to the original color . When an alternating current is applied to the degaussing coil 250-2 momentarily for 2-8 seconds in order to perform this operation, the magnetic field formed in the shadow mask in the monitor is disturbed to restore the color blurring state.

Also, the alternating current outputted through the AC rectifier 250-3 is rectified through the rectifier 250-3 and applied to the switching transformer 250-4. The switching transformer 250-4 receiving the DC applied through the rectifier 250-3 performs switching operation to supply various driving voltages required in the monitor 200 through the voltage output terminal 250-5 . At this time, if the vertical synchronization signal H-SYNC is not applied from the video card 120, the microcomputer 210 applies the suspend mode signal to the voltage regulator 250-6 to cut off the deflection voltage.

At this time, the square wave pulse outputted from the pulse width modulation (PWM) unit 250-7 causes the switching device to perform the on / off drive operation, and the change in the pulse width may increase or decrease the conduction time Thereby stabilizing the output voltage. The PWM unit 250-7 receives the power off mode signal from the microcomputer 210 and blocks the voltage supplied to the monitor 200. [ Thus, the power consumed in the monitor 200 is saved.

If the microcomputer 210 incorporated in the conventional monitor does not take into consideration the heat-radiating material and the cooling fan, malfunction occurs during operation of the microcomputer 210, and if the microcomputer 210 gets worse, it causes the inside of the microcomputer 210 to deteriorate do.

Accordingly, the present invention provides a microcomputer protection circuit and method for protecting the microcomputer by sensing the temperature of the monitor used in the monitor and the temperature inside the monitor, and automatically shutting off the power supplied to each circuit part of the monitor when the temperature is increased to a predetermined temperature .

1 is a block diagram showing an internal circuit of a conventional monitor which is generally used;

2 is a block diagram of a microcomputer protection circuit according to the present invention;

FIG. 3 is a circuit diagram showing a built-in temperature sensor unit and an external temperature sensor unit according to the present invention,

4 is a detailed circuit diagram of a microcomputer and a key operation unit according to the present invention,

5 is a circuit diagram showing a video preamplifier according to the present invention, an OSD and a video cutoff portion in detail,

6 is a flowchart showing a flow of operation of the microcomputer protection circuit according to the temperature change according to the present invention.

FIG. 2 is a block diagram of a microcomputer protection circuit according to the present invention. FIG. 2 is a block diagram of a microcomputer according to the present invention. FIG. 2 is a block diagram of a microcomputer according to the present invention. An external temperature sensor unit 30 attached to the external case of the monitor for sensing the temperature around the monitor and outputting a sensed external temperature signal of the monitor, A video card 40 for outputting a horizontal synchronizing signal H-SYNC and a vertical synchronizing signal V-SYNC for synchronizing the video signals R, G and B with the video signals R, G and B, SYNC and a vertical synchronization signal V-SYNC output from the video card 40 and receives a key signal output from the key operation unit 10, (20) A microcomputer 50 for receiving a monitor internal temperature signal and a monitor external temperature signal outputted from the external temperature sensor unit 30 and comparing the applied monitor internal temperature signal with a monitor internal temperature signal to output a power off signal, A power supply circuit 60 for receiving a power off signal output from the microcomputer 50 and shutting off the power consumed in the monitor, and an OSD processing unit for receiving and receiving information data on a temperature signal output from the microcomputer 50 An on-screen display (OSD) 70 for outputting an OSD signal, a horizontal synchronizing signal H-SYNC and a vertical synchronizing signal V-SYNC output from the microcomputer 50, A video preamplifier 80-1 for receiving the video signals R, G and B outputted from the video card 40 and amplifying them to a predetermined level to output the video signals R, G and B, A video output amplifier 80-2 for finally amplifying the video signals R, G and B outputted from the video preamplifier 80-1 and a video output amplifier 80-2 for outputting video signals R A video cutoff unit 80-3 for receiving the video signals G and B from the video cutoff unit 80-3 and adjusting the cutoff gain of the video signal, R, G, and B) and displays them.

The operation according to this will be described as follows.

There is always a lot of heat in the monitor due to a lot of circuits using high voltage. When the heat is generated and the generated heat becomes worse, heat is applied to the microcomputer 50 controlling the respective circuit parts inside the monitor. If the microcomputer 50 receives the heat generated in the monitor, malfunction may occur during the operation of the microcomputer, thereby causing a cause of deterioration in the microcomputer 50. In addition, when the temperature around the monitor is high and the heat generated inside the monitor can not be emitted, the microcomputer 50 in the monitor receives more heat and causes a malfunction.

In order to solve this problem, the user uses the key operation unit 10 when the temperature of the inside and the surrounding of the monitor increases to such an extent that the microcomputer 50 can cause a malfunction due to heat. When the user uses the key operation unit 10, the key operation unit 10 generates a key signal. The key signal generated by the key operation unit 10 is input to the microcomputer 40. Upon receipt of the key signal, the microcomputer 50 receiving the key signal receives the internal temperature signal output from the internal temperature sensor unit 20 and the external temperature signal output from the external temperature sensor unit 30.

The built-in temperature sensor unit 20 for applying the internal temperature signal to the microcomputer 50 is mounted at a proper position around the microcomputer 50 inside the monitor to detect the temperature inside the monitor, particularly around the microcomputer 50. The built-in temperature sensor 20, which senses the temperature around the microcomputer 50, applies the sensed internal temperature signal to the microcomputer 50. In addition, the external temperature sensor unit 30 that senses the temperature around the monitor is mounted at an appropriate position of the external case of the monitor to sense the temperature around the monitor. The external temperature sensor 30, which senses the temperature around the monitor, applies the sensed external temperature signal to the microcomputer 50.

The microcomputer 50 receives the internal temperature signal output from the built-in temperature sensor unit 20 and the external temperature signal output from the external temperature sensor unit 30 to compare the input internal temperature and the external temperature level. The microcomputer 50, which compares the input internal temperature and the external temperature level, outputs a power-off signal when the internal temperature and the external temperature reach a predetermined level, and applies the power-off signal to the power supply circuit. The power supply circuit receiving the power off signal output from the microcomputer 50 cuts off the power supplied to each circuit portion in the monitor. The power supply circuit cuts off the power supplied to each circuit part in the monitor, so that the heat generated by the operation of each circuit part of the monitor, in particular, the heat generated in the high voltage circuit part can be cut off.

Accordingly, the heat generated in the monitor is blocked, thereby preventing the heat from being applied to the microcomputer.

The internal temperature signal and the external temperature signal output from the built-in temperature sensor unit 20 and the external temperature sensor unit 30 and the internal temperature signal output from the internal temperature sensor unit 20 and the external temperature sensor unit 30, And an OSD processing operation for allowing the user to recognize the operation of the microcomputer 50 for determining whether the temperature is equal to or higher than a predetermined level and comparing the received external temperature signal.

First, a video card 40 in a computer main body (not shown) processes video signals processed by a CPU (not shown) in the computer main body using a video card 40. The video card for image processing the data output from the CPU includes a horizontal synchronizing signal H-SYNC for synchronizing the processed video signals R, G and B with the video signals R, G and B, V-SYNC).

(H-SYNC) and a vertical synchronizing signal (V-SYNC) among a video signal (R, G, B) output from the video card 40, a horizontal synchronizing signal -SYNC) is applied to the microcomputer 50. The microcomputer 50 receiving the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V-SYNC detects whether the inputted horizontal synchronizing signal H-SYNC and vertical synchronizing signal V-SYNC are generated Thereby saving power consumed in the monitor.

The microcomputer 50 outputs the external temperature signal and the external temperature signal output from the built-in temperature sensor unit 20 and the external temperature sensor unit 30 and the output signal from the internal temperature sensor unit 20 and the external temperature sensor unit 30, And an OSD signal such as information for determining whether the external temperature signal, the internal temperature signal, and the external temperature signal are at a predetermined level. The OSD signal outputted from the microcomputer 50 is applied to the OSD 70. [

The OSD 70, which receives the OSD signal output from the microcomputer 50, processes the OSD signal and outputs an OSD gain signal. G, and B outputted through the video pre-amplifier 80-1 amplifying the OSD gain signal output from the OSD 70 and the video signals R, G, and B output from the video card to a predetermined level, B) is finally amplified by the video output amplifier 80-2 to output the video signals R, G, and B.

At this time, the cutoff level of the video signals R, G, and B output from the video output amplifier 80-2 is adjusted by the video cutoff unit 80-3. The video signal and the OSD signal to which the cutoff level is adjusted through the video cutoff unit 80-3 are applied to the CRT 90 and the video signals R, G and B are displayed.

Accordingly, when the user turns on the OSD information to confirm the information about the temperature, the OSD information is displayed through the CRT 90. [

The built-in temperature sensor unit 20 and the external temperature sensor unit 30 are used to protect the microcomputer 50 from the built-in temperature sensor unit 20 and the external temperature sensor unit 30, Will be described with reference to the accompanying drawings.

FIG. 3 is a detailed circuit diagram of the built-in temperature sensor unit and the external temperature sensor unit according to the present invention, and includes a built-in temperature sensor unit 20 for sensing a temperature inside the monitor and outputting a sensed temperature signal, A temperature sensor 30 for detecting a temperature of the monitor 20 and a temperature sensor 30 for detecting a temperature of the surroundings of the monitor 20, And a microcomputer 50 for discriminating an inputted temperature signal.

The built-in temperature sensor unit 20 includes a correction temperature sensor unit 21 for sensing a temperature inside the monitor, a first amplification stage 22 for amplifying a temperature signal output from the first correction temperature sensor unit 21, A second amplifying stage 23 for re-amplifying a temperature signal output from the first amplifying stage 22; an output amplifying stage 24 for finally amplifying and outputting a temperature signal output from the second amplifying stage 23; Respectively.

The correction temperature sensor unit 21 is constituted by a correction temperature sensor X1 for sensing the temperature inside the monitor, a capacitor C1, a variable capacitor C2 and a coil L1.

In the above configuration, the first amplification stage 22 includes a transistor Q1, a plurality of resistors R1 to R3, capacitors C3 to C5, and a coil L2.

In the above configuration, the second amplification stage 23 includes a transistor Q2, a plurality of resistors R4 to R6, a capacitor C6, and a coil L3.

In the remaining configuration, the third amplification stage 24 is composed of the transistor Q3 and a plurality of resistors R7 and R8.

The external temperature sensor unit 30 includes a second correction temperature sensor unit 31 for sensing the temperature around the monitor and a fourth amplification stage for amplifying the temperature signal output from the correction temperature sensor unit 31 A fifth amplifying stage 33 for re-amplifying a temperature signal output from the fourth amplifying stage 32 and a sixth amplifying stage 33 for finally amplifying and outputting a temperature signal output from the fifth amplifying stage 33, 34).

The correction temperature sensor unit 31 includes a correction temperature sensor X2 for sensing the temperature inside the monitor, a capacitor C11, a variable capacitor C12, and a coil L4.

In the above configuration, the fourth amplifying stage 32 includes a transistor Q4, a plurality of resistors R9 through R11, capacitors C13 through C15, and a coil L2.

In the above configuration, the fifth amplifying stage 33 includes a transistor Q5, a plurality of resistors R12 to R14, a capacitor C17, and a coil L6.

In the rest of the configuration, the sixth amplification stage 34 includes the transistor Q6 and a plurality of resistors R15 and R16.

The operation according to this will be described as follows.

The built-in temperature sensor unit 20 driven by receiving the driving voltage V _CC1 mounts the first correction temperature sensor unit 21 at an appropriate position around the microcomputer 50 inside the monitor. The correction temperature sensor X1 of the first correction temperature sensor unit 21 is turned on when the key signal of the key operation unit 10 is applied, It senses the internal temperature.

The crystal temperature sensor (X1) that detects the temperature inside the monitor oscillates while vibrating. Since the signal of the frequency oscillated by the correction temperature sensor X1 is weak, the oscillation is compensated through the coil L1 and the capacitor C1. At this time, the compensated oscillated frequency is finely adjusted using the variable capacitance capacitor C2 and applied to the base end of the transistor Q1 of the first amplification stage 22. [ The compensated frequency input to the base end of the transistor Q1 of the first amplification stage 22 is amplified and output to the emitter stage. At this time, the resistors R1 and R2 divide the driving voltage V _CC1 , and the coil L1 and the capacitors C3 and C4 feedback the frequency amplified and outputted by the emitter terminal, Stabilizes the output. Also, the capacitor C5 and the resistor R3 are used for noise removal.

The frequency is applied to the base end of the transistor Q2 of the second amplification stage 22 through the coupling capacitor C6 in order to re-amplify the frequency according to the temperature signal amplified first in the first amplification stage 22. Amplifies the frequency applied to the base end of the transistor Q2 and outputs it to the collector stage. At this time, the resistor R4 and the resistor R5 of the second amplification stage 23 divide the driving voltage V _CC1 , and the resistor R6 and the capacitor C7 are used to remove noise. Further, the coil L3 is used as a line filter to prevent the inflow of fine AC noise into the collector end of the transistor Q2.

The frequency outputted from the emitter terminal of the transistor Q2 is applied to the base end of the transistor Q3 of the third amplifying stage 24 through the coupling capacitor C10. The transistor Q3 receiving the frequency as the base terminal finally amplifies the frequency according to the temperature signal and outputs the amplified signal. The uncharacterized capacitors C8 and C9 prevent the drive voltage V _CC1 applied to the first and second amplification stages 22 and 23 from being applied to the third amplification stage 24 as the final output amplification stage Lt; / RTI >

The frequency signal according to the temperature amplified and outputted through the transistor Q3 is applied to the microcomputer 50.

On the other hand, the external temperature sensor unit 30, which is driven by receiving the driving voltage V _CC2 , mounts the second correction temperature sensor unit 31 at a proper position of the monitor external case. The correction temperature sensor X2 of the second correction temperature sensor unit 31 is controlled such that the key signal of the key control unit 10 is applied to the second correction temperature sensor unit 31, The temperature is sensed.

A crystal temperature sensor (X2) that senses the temperature around the monitor oscillates the frequency through vibration. Since the signal of the frequency oscillated by the correction temperature sensor X2 is weak, the oscillation is compensated through the coil L4 and the capacitor C11. At this time, the compensated oscillated frequency is finely adjusted using the variable capacitance capacitor C12 and applied to the base end of the transistor Q4 of the fourth amplification stage 32. [ The frequency applied to the base end of the transistor Q4 of the fourth amplification stage 32 is amplified and output to the emitter stage. At this time, the resistors R9 and R10 distribute the driving voltage V _CC2 and the coil L2 and the capacitors C13 and C14 feed back the frequency amplified and outputted by the emitter terminal, Thereby stabilizing the output of the inverter. Further, the capacitor C15 and the resistor R11 are used for noise elimination.

The frequency is applied to the base end of the transistor Q5 of the fifth amplification stage 32 through the coupling capacitor C16 in order to re-amplify the frequency according to the temperature signal amplified first in the fourth amplification stage 32. [ The transistor Q5 re-amplifies the frequency applied to the base end and outputs it to the collector stage. At this time, the resistor R12 and the resistor R13 of the fifth amplifying stage 33 divide the driving voltage V _CC2 , and the resistor R14 and the capacitor C17 are used to remove noise. Further, the coil L6 is used as a line filter to prevent the inflow of fine AC noise into the collector end of the transistor Q5.

The frequency outputted from the emitter terminal of the transistor Q5 is applied to the base end of the transistor Q6 of the sixth amplifying stage 34 through the coupling capacitor C16. The transistor Q6 receiving the frequency as the base terminal finally amplifies the frequency according to the temperature signal and outputs it. The uncharacterized capacitors C18 and C19 prevent the driving voltage V _CC2 applied to the fourth amplifying stage 32 and the fifth amplifying stage 33 from being applied to the sixth amplifying stage 34 as the final output amplifying stage Lt; / RTI >

And the frequency signal according to the temperature amplified and outputted through the transistor Q6 is applied to the microcomputer 50. [

Therefore, the frequency output from the transistor Q3 of the third amplification stage 24, which is the final amplification output terminal of the built-in temperature sensor 20, becomes the internal temperature signal, and the final amplification output terminal of the external temperature sensor 30 6 The frequency outputted from the transistor Q6 of the amplification stage 34 becomes the external temperature signal.

The microcomputer 50 receiving the internal temperature signal and the external temperature signal output through the transistors Q3 and Q6 senses and compares the internal and external temperature signals. If the internal temperature signal and the external temperature signal exceed the predetermined temperature level, The power supplied to the circuit portion is cut off, thereby preventing the temperature inside the monitor from rising.

Hereinafter, the operations of the microcomputer 50 and the key operation unit 10 will be described in detail with reference to the accompanying drawings.

FIG. 4 is a detailed circuit diagram of a microcomputer and a key operation unit according to the present invention. The key operation unit 10 outputs a key signal when operated to reduce malfunction caused by heat generated in the monitor. And a microcomputer 50 for receiving the internal temperature signal and the external temperature signal and determining the level of the applied internal and external temperature signals.

The key operation unit 10 includes a first switch SW1 for turning on only the built-in temperature sensor unit 20 for measuring the temperature inside the monitor and an external temperature sensor unit 30 for measuring the temperature outside the monitor, A third switch SW3 for turning on both the second switch SW2 for turning on and off the built-in temperature sensor unit 20 for measuring the temperature inside the monitor and the external temperature sensor unit 30 for measuring the outside of the monitor have.

The microcomputer 50 includes a temperature signal input terminal 50-1 for receiving internal and external temperature signals, a crystal oscillation unit 50-2 for supplying a constant clock to the microcomputer 50, A horizontal and vertical synchronizing signal input terminal 50-3 to which a horizontal synchronizing signal H-SYNC and a vertical synchronizing signal V-SYNC output from a horizontal synchronizing signal input terminal (shown in FIG. 2) (H-SYNC) and a vertical synchronization signal (V-SYNC) output from the video card, an internal temperature signal and an external temperature signal output from the temperature signal input terminal 50-1 The microcomputer 50 receives and processes an input signal to output a control signal of each circuit unit of the monitor 50-4 and an internal temperature signal and an external temperature signal input from the microcomputer 50 And a display unit 50-5 for indicating that it is in progress The.

In such a configuration, the crystal oscillator 50-2 includes the quartz crystal element X3 and a plurality of capacitors C21 and C22.

The horizontal and vertical synchronizing signal input terminals 50-3 include a plurality of Zener diodes ZD1 and ZD2 and a plurality of resistors R20, a capacitor C20 and a coil L8.

In the above configuration, the display portion 50-5 includes the transistor Q7, a plurality of resistors R23 and R24, and a plurality of light emitting diodes LED1 and LED2.

In the remaining configuration, the output stage 50-4 includes a plurality of resistors R25 to R30.

The operation according to this will be described as follows.

First, a first key signal is generated when the user turns on the first switch SW1 of the key operation unit 10 to protect the microcomputer 50 according to the temperature rise inside the monitor. The first key signal generated by turning on the first switch SW1 by the user is applied to the microcomputer 50 through the resistor R17. The microcomputer 50 receiving the first key signal selects and receives only the internal temperature signal from the temperature signal input terminal 50-1.

The microcomputer 50 receiving the internal temperature signal determines the level of the input temperature signal using the built-in temperature control program. If the input internal temperature signal is equal to or higher than a predetermined constant level, the microcomputer 50 determines that the internal temperature signal is a power-off signal. The power-off signal output from the microcomputer 50 is received by the power supply circuit 60 and cuts off the power consumed by the monitor, thereby protecting the microcomputer 50 from heat generated by the supplied power.

The microcomputer 50 for receiving and processing the internal temperature signal output from the built-in temperature sensor unit 20 receives information about the processed internal temperature signal and information about the internal temperature signal input from the built-in temperature sensor unit 20 OSD data for allowing the user to recognize the OSD data. The input / output unit of the microcomputer 50 for displaying the OSD data generated by the microcomputer 20 on the monitor screen will be described below.

A clock is required to process the execution command and data in the microcomputer 50. This clock is supplied from the correction / oscillation unit 50-2 and processes the execution command and data. The quartz crystal oscillator 50-2 for supplying the clock to the microcomputer 50 oscillates through the quartz crystal oscillator X3 and generates a clock. At this time, the capacitor C21 stabilizes the oscillation frequency. The capacitor C22 adjusts the amplitude. If the value of the capacitor C21 is large, the amplitude of the frequency becomes large, and when the capacitor C22 is large, the amplitude of the frequency is small. In this manner, the microcomputer 50 is executed using the clock oscillated and output through the crystal oscillation unit 50-2.

The microcomputer 50 is executed using the clock oscillated and outputted through the crystal oscillator 50-2 and the horizontal synchronizing signal H-SYNC inputted through the horizontal and vertical synchronizing signal input terminals 50-3 is inputted to the resistance R20 and the Zener diode ZD1 and is supplied to the input terminal of the microcomputer 50 by being induced in the coil L7 according to the charging and discharging of the capacitor C20. The vertical synchronization signal V-SYNC is input by maintaining the level of the vertical synchronization signal input by the resistors R21 and ZD2 and by removing the fine AC noise input through the coil L8.

The microcomputer 50 outputs the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal H-SYNC through the output stage 50-4 according to the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V- The signal V-SYNC is outputted. The microcomputer 50 also controls the resistor R25 in the output stage 50-4 in order to control the video signal displayed on each monitor in accordance with the input horizontal synchronization signal H-SYNC and vertical synchronization signal V- And a control signal output from the direct current voltage (5V) induced through the resistor R30 and the direct current voltage 12V induced through the resistor R30 will be described below for each resistor.

A vertical shift (V-SHIFT) signal received by receiving a DC voltage (5V) through the resistor (R25) in the resistor is a control signal for moving the vertical image displayed on the monitor screen up and down. A vertical size (V-SIZE) signal synchronously output through the resistor R26 is a signal for determining the size (size) of the vertical image displayed on the monitor screen, and the DC voltage (TRAPEZOID) signal, which is supplied with a signal (5V), is a signal for correcting a phenomenon in which an image displayed on a monitor screen is distorted in a trapezoidal manner. In addition, the side pin (SIDE-PIN) signal received by receiving the DC voltage (5V) induced through the resistor R28 is a signal for correcting the distortion of the image displayed on the monitor screen.

The horizontal shift (H-SHIFT) signal received by receiving the DC voltage 5V induced through the resistor R28 is a signal that horizontally displayed on the screen of the monitor moves left and right. Also, the horizontal size (H-SIZE) signal outputted after receiving the DC voltage 12V induced through the resistor R30 is a signal for determining the horizontal size of the video signal displayed on the screen of the monitor.

The output terminal 50-4 processes the input internal temperature signal and the input internal temperature signal processed by the temperature control program built in the microcomputer 50 and outputs the determined information to the OSD processing And outputs the OSD data. A clamp signal CLAMP for making the gains of the video signals R, G, and B constant is output from the horizontal signal H-OUT while the horizontal signal H-OUT and the vertical signal V- .

On the other hand, when the internal temperature signal is processed through the microcomputer 50, the display unit 50-5 for displaying such operation outputs only the high signal to turn on the light emitting diode LED1. When the light emitting diode LED1 is turned on, the user recognizes that the microcomputer 50 is processing the current internal temperature signal.

In the same way, when the user turns on the second switch SW2 in the key operation unit 10 to generate the second key signal, the microcomputer 50 receives the external temperature signal outputted from the external temperature sensor unit 30 The external temperature signal level is determined. When the external temperature signal level is higher than a predetermined external temperature signal level, the microcomputer 50 outputs a power off signal. The power-off signal output from the microcomputer 50 is input from the power supply circuit and cut off the power supplied to each circuit part of the monitor, thereby preventing the generation of heat due to the power consumed by each circuit part in the monitor, thereby protecting the microcomputer 50 do.

The microcomputer 50 applies a low signal to the display unit 50-5 in order to display the operation of turning on the second switch SW2 of the key operation unit 10 and processing the external temperature by the microcomputer 50 . The display unit 50-5 receiving the low signal output from the microcomputer 50 turns off the transistor Q7 and turns on the light emitting diode LED2. When the light emitting diode LED2 of the display unit 50-5 is turned on, the user recognizes that the external temperature signal is being processed by the microcomputer 50 at present. In addition, when all of the light emitting diodes LED1 and LED2 of the display unit are off, this means that the current monitor is off.

When the third switch SW3 of the remaining key operation unit 10 is turned on and the third key signal is outputted, the microcomputer 50 outputs the internal key signal to the internal temperature sensor unit 20 and the external temperature sensor unit 30, The temperature signal and the external temperature signal are received to determine the internal temperature signal level and the external temperature signal level. When the internal temperature signal level and the external temperature signal level determined through the microcomputer 50 become higher than the predetermined internal temperature signal level and the external temperature signal level, a power off signal is output. The power-off signal output from the microcomputer 50 is received by the power supply circuit. The power supply circuit 60 receiving the power off signal cuts off the power supplied to each circuit part in the monitor to block the heat generated in the monitor and protect the microcomputer 50.

The microcomputer 50 repeatedly outputs the high and low signals to display the operation by processing the internal temperature signal and the external temperature signal in the microcomputer 50 by turning on the third switch SW3 of the key operation unit 10, . The transistor Q7 receiving the high and low repetition signals output from the microcomputer 50 turns on the light emitting diode LED1 when the transistor Q7 is a high signal. Also, the light emitting diode LED2 is turned on when the signal is a low signal. Accordingly, when the light emitting diode LED1 and the light emitting diode LED2 of the display unit 50-5 are periodically turned on / off, the user recognizes that the current microcomputer 50 processes the internal temperature signal and the external temperature signal .

Therefore, the user knows which temperature signal is being processed by the microcomputer 50 while watching the on / off operation of the light emitting diodes LED1 and LED2 of the display unit 50-5.

Hereinafter, signals output through the output terminal of the microcomputer 50 will be described in detail with reference to the accompanying drawings.

5 is a detailed circuit diagram of a video preamplifier, an OSD, and a video cutoff unit according to an embodiment of the present invention. The OSD 70 receives OSD data output from the microcomputer 50, processes the OSD, and outputs an OSD gain signal. A video preamplifier 80-1 for amplifying a video signal output from the video card to a predetermined level and a video preamplifier 80-1 for amplifying video signals R, G, B output from the video pre- A video output amplifier 80 and a video cut-off unit 80-2 and 80-3 for finally amplifying the OSD signal outputted from the video output amplifier and adjusting the cutoff level of the video signals R, G and B, And a CRT 90 for receiving and displaying the video signals R, G, and B output from the video cut-off units 80-2 and 80-3.

The OSD 70 includes an amplifying circuit 71 for amplifying an R-transistor transistor logic (TTL) signal, a G-TTL signal, and a B-TTL signal output from the OSD 70, And a plurality of resistors R37 to R51. The amplifying circuit 71 includes a plurality of transistors Q8 to Q10 and a plurality of resistors R52 to R54 for amplifying the R-TTL signal, the B-TTL signal, and the G-TTL signal.

The video preamplifier 80-1 includes a plurality of resistors R31 to R36 for receiving the video signals R, G and B at the input terminal 80-1-1 and a plurality of capacitors C23 To C27 and a plurality of diodes D3 to D8. The output terminal 80-1-2 includes a plurality of resistors R55 to R59 and a plurality of variable resistors VR1 to VR3 for outputting the video signals R, G and B amplified to a predetermined level, And capacitors C33 to C35.

The video output amplifier and the video cutoff units 80-2 and 80-3 may include a plurality of transistors Q10 to Q14 for final amplifying the input video signals R, A plurality of resistors R61 to R73, a plurality of capacitors C36 to C38, and a plurality of coils L7 to L9.

The operation according to this will be described as follows.

(SCD) signal and OSD data (SDA) for setting a space for storing data in the OSD signal for OSD processing of the data on the result of receiving the internal temperature signal and the external temperature signal through the microcomputer 50 . The OSD 70, which is supplied with a serial clock line (SCL) signal and a serial data (SDA) output from the microcomputer 50, generates a horizontal flyback (H-FLB) Bias of the video signal (R, G, B), that is, R-Bias, G-Bias and B-Bias, and processes the OSD signal.

When the OSD signal is processed in the OSD 70, the OSD 70 transmits the gain signals R-Gain, G-Gain and B-Gain of the video signals R, G and B, Signal and a B-TTL signal. The gain signals R-Gain and B-Gain of the video signals R, G and B outputted from the OSD 70 are supplied to the video preamplifiers 80-1 . At this time, the R-Gain signal applied through the resistor R40 receives the DC voltage 5V appropriately distributed through the resistors R47 and R48, and applies the DC voltage 5V to the video preamplifier 80-1. At this time, the capacitor C30 is used to prevent counter electromotive force.

The G-gain signal applied through the resistor R41 is applied to the video preamplifier 80-1 after receiving the DC voltage 5V appropriately distributed through the resistors R45 and R46. At this time, the capacitor C31 is used to prevent counter electromotive force. The B-Gain signal applied through the resistor R42 is applied to the video preamplifier 80-1 by receiving the DC voltage 5V appropriately distributed through the resistors R43 and R44. At this time, the capacitor C32 is used to prevent counter electromotive force.

The R-TTL signal, the G-TTL signal, and the B-TTL signal output from the OSD 70 are supplied to the transistors Q8, Q9, and Q10 of the amplifier circuit 71, To the base end. The R-TTL signal, the G-TTL signal, and the B-TTL signal are applied to the base end of each of the transistors Q8, Q9, and Q10 as digital video signals R, G, ), Which is an OSD gain signal. At this time, the resistors (R52, R53, R54) are used as emitter resistors.

The gain signals R-Gain G-Gain and B-Gain of the video signals R, G and B outputted from the OSD 70 are input to the video preamplifiers R, (R, G, B) output from the video card 40 (shown in FIG. 2). The capacitors C23, C25 and C27 are used for matching the input terminals of the video preamplifier 80-1 when the video signals R, G and B outputted from the video card 40 are inputted.

The diodes D4, D6 and D8 prevent the counter electromotive force of the negative polarity of the input video signals R, G and B while the diodes D3, D5 and D7 prevent the negative polarity electromotive force, G and B are stabilized and the capacitors C24, C26 and C28 are connected to the video preamplifier 80-1 and the resistors R33 and R32 and the resistors R33 and R34 and the resistors R35 and R36 stabilize the applied video signals R, R, G, and B applied to the input terminal are prevented from flowing to the input terminal.

Gain G-Gain of the video signals R, G and B outputted from the video card 40 and the video signals R, G and B according to the OSD signals outputted from the OSD 70, , B-Gain) are amplified up to a predetermined level, and the video pre-amplifier 80-1 outputs the video signals R, G and B and the video signals R, G and B according to the OSD. The gains of the video signals R, G and B outputted from the video pre-amplifier 80-1 and the video signals R, G and B according to the OSD signals are adjusted using the variable resistors VR1, VR2 and VR3 do.

Therefore, when the gain is adjusted through the variable resistors VR1, VR2 and VR3, the video drive signals R-DRIVE, G-DRIVE and B-DRIVE are applied to the video preamplifier 80-1, And R, G and B output according to the OSD signal are outputted. At this time, the capacitors C33, C34 and C35, which have not yet been described, prevent the reverse of the video drive signals R-DRIVE, G-DRIVE and B- R and G and B according to the OSD signal and the video signals R, G and B outputted through the output terminals 82 of the resistors R5 and R59 and the resistors R57 and R58, respectively, R60 to the video output amplifier and video cutoff portions 80-2 and 80-3.

At this time, if the OSD select signal OSD SELECT applied to the video pre-amplifier 80-1 is applied to the video pre-amplifier 80, the video pre-amplifier 80-1 outputs the video signals R, G , B) to the video output amplifier and video cutoff units (80-2, 80-3).

Video output amplifiers and video cutoff units 80-2 and 80-3 receiving the video signals R, G, and B according to the OSD signals are connected to the transistors Q10, Q11, Q12 and amplifies the video signals R, G and B according to OSD signals outputted from the base ends of the transistors Q13, Q14 and Q15, And L11 to apply the resistors R65, R68 and R73 to the respective cathodes RK, GK and BK of the video signals R, G and B of the CRT 90 to be displayed on the monitor screen .

If the OSD select signal OSD SELECT applied to the video pre-amplifier 80-1 is not selected, the video signals R, G, and B output from the video card 40 are input to the video signals R, G, and B) and is applied to the CRT 90 to display a video signal on a monitor screen.

Accordingly, when the OSD selection signal OSD SELECT applied to the video preamplifier 80-1 is input, the OSD screen is displayed on the CRT 90 so that the display door user can check the temperature information.

The flow of such an operation will be described below with reference to the accompanying drawings.

6 is a flowchart illustrating a method of operating the microcomputer protection circuit according to the present invention. The microcomputer 50 turns on the key operation unit 10 to protect the microcomputer 50 from temperature, (S51) for executing the temperature control program and a step S51 for detecting the internal temperature signal outputted from the built-in temperature sensor unit 20 when the control program is executed in the start step (S51) in which the microcomputer 50 executes the temperature control program A step S53 of detecting an external temperature signal outputted from the external temperature sensor unit 30 when the control program is executed in the start step S51 in which the microcomputer 50 executes the temperature control program, It is determined whether the internal temperature signal and the external temperature signal sensed in the step S52 for sensing the internal temperature signal and the step S53 for sensing the external temperature signal are predetermined predetermined temperatures, The internal temperature signal outputted from the built-in temperature sensor unit 20 is compared with the internal temperature signal in step S54. If it is determined in step S54 that the internal temperature signal and the internal temperature signal are compared with each other, A step S55 of detecting an internal temperature signal and returning to a step S53 of sensing an external temperature signal and a step S54 of judging whether or not the internal temperature signal and an internal temperature signal are predetermined proper temperatures, A step S56 of comparing the internal temperature signal and the external temperature signal when the temperature is not a suitable temperature and outputting a power off signal for turning off the power supply circuit 60 when the compared result exceeds the proper temperature, A step S57 of causing the light emitting diodes LED1 and LED2 to blink when the power off signal is outputted and the power is turned off in the step S56 of outputting the power off signal, The step S58 of finishing the process of protecting the microcomputer 50 due to the heat generated when the light emitting diodes LED1 and LED2 blinks in the step S57 in which the LEDs 2 are blinking.

The operation according to this will be described as follows.

In step S51 of executing the temperature control program in the microcomputer 50, the user turns on the key operation unit 10 to protect the microcomputer 50 in the monitor when the monitor attention and the temperature inside the monitor are high . When the user turns on the key operation unit 10, the key operation unit 10 outputs a key signal. The microcomputer 50 detects the key signal output from the key operation unit 10. [ The microcomputer 50 receiving the key signal output from the key operation unit 10 senses the internal temperature signal sensed and outputted by the built-in temperature sensor unit 20 through the step S52 of sensing the internal temperature signal. Also, the external temperature sensor 30 senses the external temperature signal through the step S53 of sensing the external temperature signal.

The step S54 of comparing the internal temperature signal sensed and outputted through the step S52 for sensing the internal temperature signal and the step S53 for sensing the external temperature signal and comparing the external temperature signal with the appropriate temperature is determined . That is, the proper temperature for protecting the microcomputer 50 is set in advance by the microcomputer 50 incorporating the temperature control program. For example, if the proper temperature for preventing the microcomputer 50 from malfunctioning due to heat is 50 ° C or less in the case of the inside of the monitor, the appropriate temperature is set at 50 ° C or lower and stored in the microcomputer 50 in advance. The temperature control program senses the internal temperature signal outputted from the built-in temperature sensor unit 20 by using an appropriate temperature of 50 DEG C or lower and judges the input internal temperature signal.

Also, if the temperature around the monitor is high, the heat generated inside the monitor can not be easily released. Therefore, if the proper temperature for preventing the microcomputer 50 from malfunctioning due to the temperature change around the monitor is 40 ° C or less, the appropriate temperature is set at 40 ° C or less and stored in the microcomputer 50. When the appropriate temperature is set to 40 ° C or less, the temperature control program senses the external temperature signal output from the external temperature sensor unit 30 using the appropriate temperature of 40 ° C or less and determines the input external temperature signal.

If it is determined in step S54 that the appropriate temperature is determined and compared, step S52 is performed to detect the internal temperature signal again if the internal temperature signal is not higher than the optimum temperature range of 50 DEG C and the external temperature signal is not higher than 40 DEG C, And returns to step S53 for detecting an external temperature signal.

Returning to step S52 of sensing the internal temperature signal and step S53 of sensing the external temperature signal, the internal temperature signal and the external temperature signal are sensed to exceed the proper temperature range. If the internal temperature signal and the external temperature signal level exceed the proper temperature range, the microcomputer 50 outputs a power-off signal in step S54 to determine whether the internal temperature signal and the external temperature signal are appropriate. That is, when the internal temperature signal is equal to or higher than 50 ° C or the external temperature signal is equal to or higher than 40 ° C, the microcomputer 50 outputs a power-off signal.

When the power off signal is output in step S54 for comparing and judging the appropriate temperature of the internal temperature signal and the external temperature signal, the output power off signal is received from the power supply circuit. The power supply circuit 60 receiving the power off signal output from the microcomputer 50 cuts off the power supplied to each circuit part of the monitor. When the power supplied from the power supply circuit 60 to the respective circuit parts of the monitor is cut off, the heat generated by the operation of each circuit part of the monitor is cut off and the operation of the microcomputer 50 is stopped, Protection.

In order to protect the microcomputer 50, when the power is turned off, a step S57 (S57) of detecting the internal temperature signal and the external temperature signal and flashing the light emitting diode (LED1, LED2) The light emitting diodes LED1 and LED2 are flickered. When the light emitting diodes LED1 and LED2 are turned on or off, the monitor is turned off and ends all the steps for protecting the microcomputer 50 through step S58.

As described above, the present invention has the effect of preventing the cause of the malfunction caused by the heat generated in the monitor by the microcomputer in the monitor using the temperature sensor and the deterioration of the microcomputer if it is severe.

Claims (5)

A key operation unit for outputting a key signal when operated to reduce a malfunction caused by heat generated in the monitor, a temperature sensor unit mounted inside the monitor for sensing a temperature inside the monitor and outputting a sensed temperature signal of the monitor, And a controller for receiving a horizontal synchronizing signal (H-SYNC) and a vertical synchronizing signal (V-SYNC) output from the video card, receiving a key signal output from the key operating unit, receiving a temperature signal output from the temperature sensor, A power circuit for receiving a power off signal output from the microcomputer and for shutting off a power source consumed in the monitor; and a power supply circuit for outputting information data on the temperature signal output from the microcomputer, An OSD for receiving an OSD signal and outputting an OSD signal; G and B outputted from the video card and amplifies the video signals R, G and B to a predetermined level by receiving the horizontal synchronizing signal H-SYNC and the vertical synchronizing signal V- A video preamplifier for outputting video signals R, G and B outputted from the video preamplifier, a video output amplifier for finally amplifying the video signals R, G and B outputted from the video preamplifier, And a CRT for receiving and displaying the video signals (R, G, B) output from the video cut-off unit. [2] The apparatus according to claim 1, wherein the temperature sensor unit comprises a built-in temperature sensor unit mounted inside the monitor for sensing a temperature inside the monitor, and an external temperature sensor unit attached to the monitor outer case for sensing a temperature around the monitor Microcomputer protection circuit. The microcomputer protection circuit according to claim 1, wherein the microcomputer further comprises a display unit for displaying an operation of the microcomputer. A step of sensing an internal temperature signal outputted from the internal temperature sensor unit and an external temperature signal outputted from the external temperature sensor unit when the microcomputer executes the temperature control program, A step of comparing and judging whether the temperature signal is a predetermined proper temperature and comparing the internal temperature signal with an internal temperature signal output from the temperature sensor unit when it is judged that the internal temperature signal is an appropriate temperature in a step of judging and comparing the predetermined internal temperature signal with a predetermined appropriate temperature, A step of returning to step S52 of sensing a signal and a step of returning to step S52 when the internal temperature signal and the internal temperature signal are not the proper temperature in the step of determining whether the internal temperature signal is a predetermined proper temperature, And outputting an off signal. 5. The method according to claim 4, wherein the step of outputting a power-off signal for turning off the power-supply circuit in the microcomputer further comprises a step of flashing a light-emitting diode (LED) indicating that a power- How to Protect My.