KR20070025176A - Inverter current control device of liquid crystal display - Google Patents

Abstract

The present invention relates to a current control device of an inverter for supplying a driving current to a lamp of a liquid crystal display, wherein a vertical pulse width modulation (PWM) frequency for each vertical frequency is set differently so as to recognize a vertical frequency input from a PC, A microcomputer for outputting a pulse width modulation (PWM) signal corresponding to a vertical frequency, a level shift unit for inverting / amplifying a pulse width modulation duty (PWM duty) of the pulse width modulation (PWM) signal output from the micom, and the level shift An integrating circuit unit converts a pulse width modulation (PWM) signal inverted / amplified by a negative voltage into a DC voltage and outputs the converted DC voltage to the inverter to control a lamp current. By setting the PWM frequency differently, wave noise is improved.

Description

Apparatus for controlling inverter current of liquid crystal display}

1 is a circuit diagram showing the configuration of an inverter current control device of a conventional liquid crystal display.

Figure 2 shows a conventional inverter PWM frequency.

3 is a view showing a wave noise phenomenon according to a conventional fixed PWM frequency.

Figure 4 is a circuit diagram schematically showing the configuration of the inverter current control device of the liquid crystal display according to the present invention.

5 is a diagram illustrating a PWM frequency allocated for each vertical frequency according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100, 410: micom 110, 430: integral circuit

120, 440: Inverter 400: PC

420: level shift unit

The present invention relates to an inverter current control device for a liquid crystal display that improves wave noise by setting different pulse width modulation (PWM) frequencies for each vertical frequency of an input signal.

Compared to the CRT which is a conventional display device, the liquid crystal display device has a very low power consumption, a significantly high frequency generated and a very competitive advantage in terms of volume and weight. In addition, as the display devices are gradually enlarged, existing CRT monitors have to be restricted in space, but liquid crystal display devices are gradually increasing in that such problems are solved.

Liquid crystal display devices are used directly, and various portable devices such as laptops and PDAs, and desktop computers.

On the other hand, portable devices such as laptops and PDAs have great significance in minimizing the power consumption of the product. This is because the use of the battery is a portable because of the high use of the battery, and therefore, the maximum amount of power consumption is required to maximize the battery usage time.

For this reason, recently, a portable device adopts a method of varying the frame frequency of the liquid crystal display device according to the use environment of the system. That is, to reduce the power consumption of the liquid crystal display device, the variable frequency of the liquid crystal display device is applied. .

That is, with the recent trend of increasing battery life of portable devices, the frame frequency of the liquid crystal display is varied according to the usage environment of the system. In order to reduce the power consumption of the system, it checks whether the battery use environment or the AC adapter power use environment, and arbitrarily varies the frame frequency of the liquid crystal display.

In this case, if the digital mode inverter uses a fixed PWM frequency as the brightness control information of the liquid crystal display, a screen failure occurs due to mutual interference between the PWM frequency and the frame frequency of the liquid crystal display.

Accordingly, when setting the PWM frequency of the inverter, it is set by referring to the frame frequency of the liquid crystal display. The PWM frequency is set to 15 Hz to 30 Hz larger than the frame frequency, that is, n times the vertical synchronization frequency. Becomes less than or equal to 15 Hz, the noise is more likely to appear on the liquid crystal display due to frequency interference.

Hereinafter, a method of controlling the inverter current of the liquid crystal display will be described with reference to the drawings.

1 is a circuit diagram illustrating a configuration of an inverter current control device of a conventional liquid crystal display, FIG. 2 is a diagram illustrating a conventional inverter PWM frequency, and FIG. 3 is a diagram showing a wave noise phenomenon according to a conventional fixed PWM frequency.

Referring to FIG. 1, an inverter current control apparatus of a liquid crystal display may include a microcomputer 100 for outputting a control signal corresponding to a user's request, an LCD module (not shown) for displaying an image signal, and supplying a light source to the LCD module. A plurality of lamps (not shown) mounted behind the lower glass substrate of the LCD module, an integrated circuit unit 110 for converting a pulse width modulation (PWM) signal output from the microcomputer into a DC voltage, and the integrated circuit unit 110. Inverter 120 to supply driving power to the lamp according to the output and the control signal of the microcomputer 100, so that the duty according to the DC voltage to the PWM generated by the OSC at a fixed frequency to the inverter 120 is variable It includes a second capacitor (C2).

The integration circuit unit 110 includes a first resistor R1 and a first capacitor C1.

The inverter 120 generates a frequency of the output voltage in synchronization with the PWM frequency component output from the microcomputer 100, and then outputs the light to the light emitting device of the liquid crystal display to adjust brightness. In the above process, interference occurs due to the interaction between the PWM frequency component of the inverter 120 and the frame frequency of the liquid crystal display, thereby causing noise to appear on the screen of the liquid crystal display.

That is, if the duty of the PWM output of the microcomputer 100 is changed and output when the resolution is changed, the DC voltage converted by the integrating circuit unit 110 is transmitted to the controller of the inverter 120. Then, the controller receives the voltage and varies the duty according to the DC voltage to the PWM generated by the OSC at a frequency fixed by the second capacitor C2 to operate the lamp in the on-period and in the off-period. The wider the interval, the brighter the brightness. The narrower the brightness, the darker the screen brightness.

In the inverter PWM control method, a large current change occurs because the lamp is operated / stopped by the on / off section of the backlight current change. At this time, the change of the current affects the module side on the GND, and current ripple occurs.

This is because the current LCD panel is shielded with data layer on the ACT layer side when it is produced by applying 5 masks, so that the inverter current ripple does not affect, but the current ripple generated in the on / off period of the inverter is changed to 4 mask. Photo leakage will affect the side, and the coupling between the ACT and Vcom terminals will eventually cause the drive ripple to load on Vcom, causing wave noise.

When the PWM mode in the inverter brightness control, the PWM frequency has a frequency of 'A' shown in Figure 2 uniformly to all the PC signal vertical frequency, this PWM frequency is shown in Figure 3 with respect to the vertical frequency input from the PC This causes problems such as wave noise, which is severely seen in a section where the PWM frequency of the inverter 120 coincides with a half of the vertical frequency of the PC signal.

With single inverter PWM frequency, it is difficult to improve wave noise for all PC vertical frequencies 56/60/70/72 / 75Hz which are input variously, and the PWM frequency produced by inverter oscillator is also high depending on the temperature characteristics of external components. As it changes, it is impossible to improve wave noise by the vertical frequency of all PC signals.

As described above, since the PWM frequency for adjusting the LCD lamp current is set by changing the capacitance value of the external capacitor, the external capacitor changes the capacitance value according to the temperature, and at this time, the PWM frequency is also changed, so that the brightness is changed due to the changed frequency. There is a disadvantage that the wave noise of the screen occurs.

Accordingly, it is an object of the present invention to provide an inverter current control device for a liquid crystal display which can improve wave noise by changing an on / off frequency of an inverter lamp using a PWM signal.

Another object of the present invention is to provide an inverter current control device of a liquid crystal display for variably adjusting the PWM frequency of the inverter for adjusting the brightness of the liquid crystal display in conjunction with the frame frequency of the liquid crystal display.

It is still another object of the present invention to provide an inverter current control apparatus for a liquid crystal display which controls the PWM frequency of the inverter for adjusting the brightness of the liquid crystal display to be automatically converted into an optimum frequency without frequency interference.

According to an aspect of the present invention to achieve the above objects, in the current control device of the inverter for supplying a drive current to the lamp of the liquid crystal display, the vertical frequency pulse width modulation (PWM) frequency is set differently, from the PC Recognizing the input vertical frequency, and outputs a pulse width modulation (PWM) signal corresponding to the recognized vertical frequency, the pulse width modulation duty (PWM duty) of the pulse width modulation (PWM) signal output from the micom An inverting / amplifying level shifting unit, an integrating circuit unit converting a pulse width modulation (PWM) signal inverted / amplified in the level shifting unit into a DC voltage and outputting the converted DC voltage to the inverter to control a lamp current And a voltage divider resistor connected in parallel with the integrating circuit unit to control a voltage passing through the integrating circuit unit to a desired voltage. A current control resistor connected in series with the integrating circuit unit and connected in parallel with the voltage distribution resistor so that current is controlled with respect to a voltage passed through the voltage distribution resistor, and in series between the current control resistor and the inverter. Is connected, the inverter current control device for a liquid crystal display comprising a diode for controlling the reverse flow of the current to the voltage passed through the current control resistor and transmits the voltage to the inverter.

The level shift unit includes a transistor, a first resistor connected between the transistor and the microcomputer, and a second resistor connected between the transistor and a power supply Vcc.

The pulse width modulation (PWM) frequency set differently for each vertical frequency is a distant frequency avoiding the point of meeting a half multiple of the vertical frequency.

When the high signal is applied, the inverter is activated to light the lamp, and adjusts the brightness of the lamp by the DC voltage input through the diode.

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

4 is a circuit diagram schematically showing the configuration of an inverter current control device of a liquid crystal display according to the present invention. FIG. 5 is a diagram showing a PWM frequency allocated for each vertical frequency according to the present invention.

Referring to FIG. 4, the inverter current control device of the liquid crystal display has a pulse width modulation (PWM) frequency set for each vertical frequency differently, so as to recognize the vertical frequency input from the PC 400, and to the recognized vertical frequency. A microcomputer 410 for outputting a corresponding pulse width modulation (PWM) signal, an LCD module (not shown) for displaying an image signal, and a plurality of pixels mounted behind a glass substrate under the LCD module to supply a light source to the LCD module. A ramp (not shown), a level shift unit 420 for inverting / amplifying a pulse width modulation duty (PWM duty) of a pulse width modulation (PWM) signal output from the microcomputer 410, and in the level shift unit 420 An integrating circuit unit 430 for converting an inverted / amplified pulse width modulation (PWM) signal into a DC voltage, and connected in parallel with the integrating circuit unit 430 so that the voltage passing through the integrating circuit unit 430 becomes a desired voltage. My For example, the voltage distribution resistor R4 and the integrating circuit unit 430 are connected in series, and are connected in parallel with the voltage distribution resistor R4 so that a current is applied to the voltage passing through the voltage distribution resistor R4. The current control resistor R5, which is controlled to be controlled, is connected in series between the current control resistor R5 and the inverter 440, and controls the reverse flow of current with respect to the voltage passing through the current control resistor R5 to control the corresponding voltage. A diode (D1) for transmitting to the inverter 440, an inverter (440) for supplying driving power to the lamp in accordance with a control signal output through the diode (D1), and a second capacitor (C2).

Here, the level shift unit 420 is connected between a transistor Q1, a first resistor R1 connected between the transistor Q1 and the microcomputer 410, and between the transistor Q1 and a power supply Vcc. And a second resistor R2.

As shown in FIG. 5, the micom 410 has a different pulse width modulation (PWM) frequency for each vertical frequency. Therefore, according to the frequency input as the floating PWM frequency, the frequency of 'A' shown in FIG.

To improve the wave noise, set the PWM frequency as far as possible by avoiding the half of the vertical frequency of the input signal, and set the optimum frequency where the wave noise does not come out according to the vertical frequency of the PC signal. Can be.

In addition, the microcomputer 410 recognizes the vertical frequency of the signal input from the PC 400, and outputs a PWM frequency corresponding to the recognized vertical frequency.

For example, if the vertical frequency of the input PC signal is 56 Hz, the microcomputer 410 outputs 238 Hz, which is a PWM frequency corresponding to the 56 Hz.

The microcomputer 410 may recognize the vertical frequency of the PC signal and improve wave noise by differently setting the frequency at which the module lamp current is turned on / off using a PWM output signal corresponding to the vertical frequency. .

The level shifter 420 inverts / amplifies the PWM signal output from the microcomputer 410 and transmits the PWM signal to the integrator circuit 430. That is, the level shifter 420 inverts the signal 'low' if the signal output from the microcomputer 410 is a 'high' signal, and inverts the signal 'high' if the signal is 'low'.

The integrating circuit unit 430 converts the pulse width modulation (PWM) signal inverted / amplified by the level shifting unit 420 into a DC voltage, and the user desires the voltage V0 through the voltage distribution resistor R4. Set to be The voltage V0 is a voltage applied to the controller of the inverter 440 without problem, and by applying an arbitrary voltage to the second capacitor C2, the frequency of the triangular wave that determines the PWM frequency can be varied, and the wave The frequency at which noise is generated can be avoided.

The voltage passing through the voltage distribution resistor R4 is controlled by the current control resistor R5, and current reverse flow is removed through the diode D1 to be transmitted to the inverter 440.

That is, a current is connected in series between the current control resistor R5 and the inverter 440 to allow the current to be controlled with respect to the voltage passed through the voltage distribution resistor R4 to the voltage passed through the current control resistor R5. The reverse flow of the current is controlled to transmit the corresponding voltage to the inverter 440, and the inverter 440 supplies driving power to the lamp according to a control signal output through the diode D1.

When the 'high' signal is applied, the inverter 440 is activated to turn on the lamp built in the LCD module, and the brightness of the lamp is controlled by the DC voltage input through the diode D1.

In the present invention, since the crystal output is used instead of the method of setting the frequency by the second capacitor C2 of the external inverter, the PWM frequency does not change according to external conditions and outputs a very stable frequency.

That is, the microcomputer 410 recognizes the vertical frequency of the PC signal and uses the PWM output signal corresponding to the recognized vertical frequency to set the frequency at which the lamp current for each resolution is turned on / off differently for each vertical frequency. Will improve.

Portable devices such as notebook computers and PDAs have been adopted to vary the frame frequency of the liquid crystal display according to the use environment of the system. That is, the frame frequency of the liquid crystal display is adjusted to lower the power consumption of the liquid crystal display. In conjunction with this, the inverter PWM frequency for adjusting the brightness of the liquid crystal display lamp is also changed.

The present invention is not limited to the above embodiments, and many variations are possible by those skilled in the art within the spirit of the present invention.

As described above, according to the present invention, since the PWM frequency is set differently for each PC input frequency by using a microcomputer, it is possible to provide an inverter current control apparatus for a liquid crystal display in which wave noise is improved.

Claims (5)

In the current control device of the inverter for supplying a drive current to the lamp of the liquid crystal display, A pulse width modulation (PWM) frequency for each vertical frequency is set differently, the microcomputer recognizes the vertical frequency input from the PC, and outputs a pulse width modulation (PWM) signal corresponding to the recognized vertical frequency; A level shift unit for inverting / amplifying a pulse width modulation duty (PWM duty) of a pulse width modulation (PWM) signal output from the microcomputer; and An integrating circuit unit for converting a pulse width modulation (PWM) signal inverted / amplified by the level shift unit into a DC voltage and outputting the converted DC voltage to the inverter to control a lamp current Inverter current control device of the liquid crystal display comprising a. The method of claim 1, And the level shift unit comprises a transistor, a first resistor connected between the transistor and the microcomputer, and a second resistor connected between the transistor and a power supply (Vcc). The method of claim 1, A voltage distribution resistor connected in parallel with the integrating circuit unit to control a voltage passing through the integrating circuit unit to a desired voltage; A current control resistor connected in series with the integrating circuit unit and connected in parallel with the voltage distribution resistor to control the current with respect to the voltage passing through the voltage distribution resistor; And a diode connected in series between the current control resistor and the inverter, the diode controlling the reverse flow of the current with respect to the voltage passed through the current control resistor to transmit the corresponding voltage to the inverter. Current control device. The method of claim 1, And a pulse width modulation (PWM) frequency set differently for each vertical frequency as far as possible, avoiding the point of meeting a half multiple of the vertical frequency. The method of claim 1, The inverter is activated when the high signal is applied, the lamp is turned on, and the inverter current control device of the liquid crystal display, characterized in that to adjust the brightness of the lamp by the DC voltage input through the diode.

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