KR100577791B1 - Security system of notebook computer - Google Patents

Abstract

The present invention relates to a security system using a weight sensor and an oscillator in a notebook computer using a thin film transistor liquid crystal display.

The notebook computer security system of the present invention is a notebook computer having a liquid crystal display device, comprising: a sensor unit for checking an input state in a locked state, an oscillator for converting an output signal of the sensor unit into a pulse signal of a constant amplitude, and the oscillator An alarm device for generating an alarm sound according to an output signal of the controller; It includes a switch for transmitting to the monitor.

Description

SECURITY SYSTEM OF NOTEBOOK COMPUTER}

1 is a block diagram of a security system of a notebook computer according to an embodiment of the present invention;

2 is a circuit diagram showing an internal signal control system portion of a notebook computer in the security system of FIG.

3 is a circuit diagram showing a liquid crystal module portion of a monitor in the security system of FIG.

4 is a waveform diagram showing an output signal of each node in the security system according to an embodiment of the present invention;

5 is a circuit diagram of a typical 555 timer,

6 is a circuit diagram of a general metastable multi-vibrator using the 555 timer.

(Name of the code for the main part of the drawing)

100: Internal system part of the notebook computer

200: liquid crystal module portion of the monitor

110: sensor unit 120: oscillator

130: alarm device 210: control unit

220: switching unit 111: sensor

112: comparator 121: metastable multi-vibrator

122: JK flip flop 123: buffer

124: 555 timer 211: transfer unit

212: disturbance signal generator 213, 214: JK flip flop

215: AND gate R1, R2: resistance

C: capacitor T1, T2: transfer gate

VA, VB: disturbance signal Vref: reference voltage

CPHout: Horizontal Clock Pulse Signal

The present invention relates to a notebook computer using a thin film transistor liquid crystal display (TFT-LCD), and more particularly to a sensor and a controller chip. It relates to a security system used.

Cathode Ray Tube (CRT) cathode ray tube (CRT), which is the most widely used display device, has been spotlighted as a display device including TV and computer monitor because of its easy color and fast operation speed. However, the cathode ray tube has a disadvantage in that the portability is not only thick because of the structural characteristic of securing a certain distance between the electron gun and the screen, but also because the power consumption is large and the weight is considerably heavy.

In order to overcome the disadvantages of the cathode ray tube as described above, various various display devices have been devised. Among them, the most practical device is a liquid crystal display (LCD).

Although the LCD is darker in screen and somewhat slower in operation than the cathode ray tube, each pixel may be operated according to a signal scanned on a plane without having an electron gun. It can be used as a very thin display device such as a wall-mounted TV. In addition, since the liquid crystal display device is light in weight and consumes considerably less power than the cathode ray tube, it is recognized that the liquid crystal display device is most suitable as a portable display device such as being used as a display of a battery operated notebook computer.

As the use of the notebook computer employing the liquid crystal display device as described above is gradually increasing, the interest in security of the notebook computer itself has been greatly concentrated.

However, since notebook computers are developing toward thinner slim, there are many difficulties in installing a security device without using a large area in a thin notebook computer.

An object of the present invention is to provide a security system through an interface between a weight control sensor and a controller chip of a liquid crystal display.

In order to achieve the above object, the notebook computer security system of the present invention is a sensor unit for checking the input state in the locked state, an oscillator for converting the output signal of the sensor unit into a pulse signal of a constant amplitude, and the output signal of the oscillator An alarm device for generating an alarm sound, a controller for generating a disturbance signal that distorts a screen by inputting an output signal and a horizontal clock signal of the oscillator, and an output signal of the controller according to an operation of the sensor unit. It is characterized by consisting of a switching unit for transmitting.

The sensor unit, oscillator, and alarm device are formed in a signal control system inside a notebook computer.

The control unit and the switching unit may be formed in the module portion of the liquid crystal display constituting the monitor.

The sensor unit may include a sensor for detecting a signal input state of a user, and a comparator configured to generate an output signal by comparing an output signal of the sensor with a reference voltage.

The oscillator receives an output signal of the sensor unit and generates a pulse signal of a predetermined cycle, and a duty cycle of receiving an output signal of the sensor unit and an output signal of the sensor and the metastable multi-vibrator. ) And a buffer for stably transferring the output signal of the first flip flop.

The metastable multi-vibrator is characterized by consisting of a 555 timer (Timer) and a resistor and a capacitor connected to the 555 timer.

The control unit includes a transfer unit for transmitting an output signal of the oscillator and a horizontal clock pulse according to the output signal of the sensor unit, and a disturbance signal generator for generating a disturbing signal for distorting the screen according to the output signal of the transfer unit. It features.
The transfer unit is connected in parallel to the NMOS transistor receiving the output signal of the sensor unit to the gate terminal, the first transfer gate for transmitting the output signal of the oscillator, and the NMOS transistor receiving the output signal of the sensor unit to the gate terminal in parallel And a second transfer gate for transferring a horizontal clock pulse signal.

The disturbance signal generator includes a second flip flop for generating a first disturbance signal using the output signal of the oscillator as a clock signal, a third flip flop for generating a second disturbance signal using the horizontal clock pulse as a clock signal, and the second flip flop. And an AND gate for feeding back output signals of the second and third flip flops to the reset terminal of the second flip flop and the set terminal of the third flip flop.

The switching unit may include switching means for transmitting the first disturbance signal or the second disturbance signal to a monitor when the output signal of the sensor unit is positively input.

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

1 is a block diagram of a security system of a notebook computer according to an embodiment of the present invention. Referring to FIG. 1, the security system of the notebook computer of the present invention may be largely divided into an internal control system part 100 and a liquid crystal module part 200 of the notebook computer.

The internal control system portion 100 of the notebook computer includes a sensor unit 110 for detecting an input state, an oscillator 120 for generating a pulse signal Vout1 using the output signal Vcomp of the sensor unit, and The alarm device 130 is configured to generate an alarm sound by the pulse signal Vout1 of the oscillator 120.

The liquid crystal module unit 200 receives the output signal Vcomp of the sensor unit 110, the output signal Vout1 of the oscillator 120, and the horizontal clock pulse output signal CPHout to receive a monitor display state. The controller 210 is configured to generate a distorting signal that is distorted, and the switching unit 220 transmits an output signal of the controller 210 to a monitor.

If you look at this in more detail:

FIG. 2 shows a circuit diagram of the signal control system portion 100 inside the notebook computer in the security system of FIG. 1, and FIG. 3 shows a firing diagram of the liquid crystal module portion 200 of the monitor.

Referring to FIG. 2, in the internal control system 100 of the notebook computer, the sensor unit 110 detects a signal input by a user in the sensor 111 and generates a voltage, and in the comparator 112 a reference voltage ( Vref) and the output signal of the sensor 111 are compared to generate a comparison signal Vcomp. That is, when the user presses the Enter or ESC keyboard of the keyboard in a locked state, the sensor 111 detects this to generate a voltage, and the generated voltage is a reference voltage Vref. Since it is larger, the comparator 112 generates the positive comparison signal Vcomp to operate the oscillator 120.

On the contrary, when there is no signal input in the locked state, since the reference voltage Vref has a higher potential than the output signal of the sensor 111, the comparator 112 generates a negative signal and thus the oscillator 120 Off.

In this case, the sensor 111 uses a weight sensor to detect that the keyboard is pressed in the locked state.

The oscillator 120 is for generating a pulse signal Vout1 having a predetermined amplitude, a metastable multi-vibrator 121 for inputting the output signal Vcomp of the sensor unit 110, and the metastable multi A first flip-flop 122 for generating a pulse signal having a duty cycle of 1/2 using the output signal of the vibrator 121 as a clock signal and the output signal of the sensor unit 110 as an input signal, It consists of a buffer 123 for stably transferring the output signal of one flip flop (122).

The metastable multi-vibrator 121 includes a 555 timer 124, resistors R1 and R2 and a capacitor C connected to the 555 timer 124.

5 shows an internal circuit diagram of a typical 555 timer. Referring to FIG. 5, the 555 timer 40 includes a first comparator 41, a second comparator 42, an SR flip flop 43, and a switching transistor Q1. The three resistors R having the same resistance value are connected in series to the power supply voltage Vin, so that the threshold voltage V _TH of the first comparator 41 and the threshold voltage of the second comparator 42 are connected. To form (V _TL ).

The output signal of the first comparator 41 having the threshold terminal connected to the non-inverting terminal + is connected to the reset terminal R of the SR flip flop 43, and the trigger terminal Trigger is an inverting terminal (−). The output signal of the second comparator 42 connected to) is connected to the set terminal S of the SR flip flop 43. The inverted output terminal / Q of the SR flip flop 43 is connected to the base terminal of the switching transistor Q1 through a resistor, and the collector terminal of the switching transistor Q1 is connected to the discharge terminal Discharge. The output signal Out of the 555 timer 40 is generated at the output terminal Q of the SR flip flop 43.

A metastable multi-vibrator 121 for generating a pulse signal having a constant amplitude using a 555 timer 124, the resistors R1, R2, and the capacitor C as shown in FIG. 5 is configured. The waveform diagram of the capacitor voltage Vc and the output voltage Vo with time of the metastable multi-vibrator 121 is shown.

Referring to FIG. 6, the output voltage Vo alternates between a high level section T _H having a power supply voltage Vin level and a section T _L having a low level, and a pulse signal appears, and the capacitor voltage Vc. ) Increases or decreases (exponentially) between the threshold voltage (V _TH ) of the first comparator and the threshold voltage (V _TL ) of the second comparator.

In this case, the high level section T _H is given as 0.69 × C × (R1 + R2), and the low level section T _L is given as 0.69 × C × R2, wherein the metastable multi-vibrator 121 is used. The output signal Vo is generated with a pulse having a frequency of 1.44 / [(R1 + 2R2) × C].

As described above, the output signal Vo of the metastable multi-vibrator 121 does not have a constant duty cycle. The output signal Vo is a clock signal and the output signal Vcomp of the sensor unit 110 is input. A pulse signal having a duty cycle of 1/2 is generated while passing through the JK flop 122 serving as the signals J and K.

The buffer 123 stably transmits the pulse signal to transmit the output signal Vout1 of the oscillator 120 to the alarm device 130.

When the user inputs the keyboard in the locked state, the alarm device 130 that receives the signal output from the oscillator 120 generates an alarm signal in the notebook computer internal system.

3 is used to disturb the monitor screen when a signal is input in a locked state by using the signal Vout1 output from the oscillator 120 and the output signal CPHout of a clock pulse horizontal (CPH) generator. It shows a liquid crystal module portion 200 for.

Referring to FIG. 3, the control unit 210 in the liquid crystal module portion 200 transmits an output signal Vout1 and a horizontal clock pulse signal CPHout of the oscillator 120, respectively, The disturbance signal generator 212 generates a disturbance signal (V _A , V _B ) that disturbs the display state of the monitor by using the signal transmitted from the transmission unit 211.

The transfer unit 211 includes a first transfer gate T1 for transferring the output signal Vout1 of the oscillator 120 and a second transfer gate T2 for transferring the horizontal clock pulse signal CPHout. The first and second transfer gates T1 and T2 have N-channel metal oxide semiconductor transistors (NMOS transistors) connected in parallel, and the NMOS transistors respectively output an output signal of the sensor unit 110 to a gate terminal. Received as

Therefore, when the user inputs a signal under the locked state, the transfer gates T1 and T2 are horizontally aligned with the output signal Vout1 of the oscillator 120 by the positive signal Vcomp output from the sensor unit 110. The clock pulse signal CPHout is transferred to the disturbance signal generator 212.

The disturbance signal generator 212 transfers the oscillator output signal Vout1 transmitted through the first transfer gate T1 as a clock signal through the second flip flop 213 and the second transfer gate T2. The third flip flop 214 that receives the received horizontal clock pulse signal CPHout as a clock signal and the output signals Q of the second flip flop 213 and the third flip flop 214 are input as inputs, respectively. The AND gate 215 feeds an output signal back to the reset terminal R of the second flip flop 213 and the set terminal S of the third flip flop 214.

Since the low level signal L is applied to the J input terminal and the high level signal is applied to the K input terminal, the second flip flop 213 and the third flip flop 214 perform the reset operation. The low level signal is output from both the output terminal Q of the second flip flop 213 and the third flip flop 214. At this time, since the signal output through the AND gate 215 resets the second flip flop 213 and sets the third flip flop 214, the output node Q of the second flip flop 213. ) Always generates a low level first disturbance signal V _A , and at the output node Q of the third flip-flop 214, the second disturbance signal V that varies according to the period of the horizontal clock pulse signal CPHout. V _B ) occurs.

When the user inputs a signal in the locked state and the positive output signal Vcomp generated from the sensor unit 110 is input, the switching unit 220 separates the line applying the signal to the monitor from the horizontal clock pulse line. By connecting to the first disturbance signal V _A or the second disturbance signal V _B , a normal screen is not displayed on the monitor and only a bright line is generated, or a signal is corrupted.

4 shows waveforms of the internal system output signal of the notebook computer and the disturbance signal displayed on the monitor in the liquid crystal module portion 200 of the security system shown in FIG. 3.

Referring to FIG. 4, the oscillator generates a pulse signal Vout1 having a duty cycle of 1/2 according to the reference voltage Vref, and the first disturbance signal V _A outputs only a low level signal. The disturbance signal V _B can be seen to generate a pulse signal with a constant duty cycle.

Therefore, only a bright line appears when the first disturbance signal V _A is applied to the monitor, and an abnormal data signal is generated when the second disturbance signal V _B is applied to the monitor.

As described in detail above, according to the notebook computer security system of the present invention, it is possible to manufacture a notebook computer with excellent security performance by blocking other users outside the computer when the user has set the security state. .

In addition, by using the gate and controller chips remaining on the liquid crystal module without using many components, a security system can be provided without greatly increasing the volume of the notebook computer, thereby meeting the miniaturization trend and reducing the manufacturing cost. Economics can be secured.

Hereinafter, this invention can be implemented in various changes in the range which does not deviate from the summary.

Claims (10)

Sensor unit for checking the presence of the input in the locked state, An oscillator for converting an output signal of the sensor unit into a pulse signal having a predetermined amplitude; An alarm device for generating an alarm sound according to the output signal of the oscillator; A control unit for generating a disturbing signal for distorting a screen by inputting an output signal of the sensor unit, an output signal of an oscillator, and a horizontal clock signal; And a switching unit for transmitting an output signal of the control unit to a monitor. delete The method of claim 2, wherein the sensor unit A sensor for detecting a user's signal input state, And a comparator configured to generate an output signal by comparing the output voltage of the sensor with a reference voltage. 3. The oscillator of claim 2 wherein the oscillator A metastable multi-vibrator configured to receive an output signal of the sensor unit and generate a pulse signal of a predetermined period; A flip-flop for adjusting a duty cycle by receiving an output signal of the sensor unit and an output signal of a metastable multi-vibrator, And a buffer for stably transferring the output signal of the flip flop. The method of claim 4, wherein the metastable multi-vibrator 555 timer, And a resistor and a capacitor connected to the 555 timer. The method of claim 1, wherein the control unit and the switching unit A security system of a notebook computer, characterized in that formed in the module portion of the liquid crystal display device constituting the monitor. The method of claim 6, wherein the control unit A transfer unit for transferring an output signal of the oscillator and a horizontal clock pulse using the output signal of the sensor unit; And a disturbance signal generator for generating a disturbance signal that distorts a screen according to the output signal of the transfer unit. The method of claim 7, wherein the delivery unit A first transfer gate for transmitting an output signal of the oscillator, in which an NMOS transistor receiving an output signal of the sensor unit through a gate terminal is connected in parallel; The NMOS transistor which receives the output signal of a sensor part through a gate terminal is connected in parallel, and consists of a 2nd transfer gate for transferring a horizontal clock pulse signal, The security system of the notebook computer characterized by the above-mentioned. The method of claim 7, wherein the disturbing signal generating unit A first flip flop for generating a first disturbance signal using the output signal of the oscillator as a clock signal, A second flip flop for generating a second disturbance signal using the horizontal clock pulse as a clock signal; And an AND gate which feeds the output signals of the first and second flip flops as inputs and feeds back to the reset terminal of the first flip flop and the set terminal of the second flip flop. The method of claim 9, wherein the switching unit And a switching means for transmitting the first disturbance signal or the second disturbance signal to a monitor when the output signal of the sensor unit is positively input.

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