KR20090084553A - Inverter driving circuit for liquid crystal display device - Google Patents

Abstract

An inverter driving circuit of a liquid crystal display device is provided to perform an image of high quality by performing a zero dimming control without a striking time. An inverter(31) outputs an AC voltage of a corresponding duty ratio to a backlight lamp(32) in response to a backlight control signal. A tube current detecting part(34) detects a tube current supplied to both ends of the backlight lamp from the inverter, and outputs a first tube current detecting signal and a second tube current detecting signal. A backlight control signal comparing part(35) compares the backlight control signal with a first reference voltage, and outputs a reference voltage control signal. A protecting circuit part(36) compares the first tube current detecting signal and the second tube current detecting signal with a second reference voltage, and outputs a shutdown signal to the inverter.

Description

 Inverter driving circuit of liquid crystal display device {INVERTER DRIVING CIRCUIT FOR LIQUID CRYSTAL DISPLAY DEVICE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technology for driving an inverter of a liquid crystal display device, and more particularly, an inverter driving circuit of a liquid crystal display device capable of realizing a luminance at which a backlight lamp does not light without requiring a striking time. It is about.

In recent years, with the development of information technology (IT), the importance of the flat panel display as a visual information transmission medium has been further emphasized. A liquid crystal display (LCD), which is a typical display device of such a flat panel display device, is an apparatus for displaying an image using optical anisotropy of liquid crystal, and has advantages such as thin, small size, low power consumption, and high quality.

In general, the liquid crystal display does not emit light by itself and includes a backlight unit for supplying light. The backlight unit mainly uses a Cold Cathode Fluorescent Lamp (CCFL) or an External Electrode Fluorescent Lamp (EEFL) as a light source, and the light generated from the Cold Cathode Fluorescent Lamp or the External Electrode Fluorescent Lamp. Is transmitted through the light guide plate to be projected onto the liquid crystal display under the liquid crystal display.

The characteristics of the cold cathode fluorescent lamp and the external electrode fluorescent lamp are similar to each other. However, unlike cold cathode fluorescent lamps, external electrode fluorescent lamps do not have electrodes or filaments in glass tubes, and are only used as electrodes by coating carbon or silver powder on the outer walls of the lamps. In the case of the external electrode fluorescent lamp, a capacitor is provided for each lamp, so that current can be distributed when the lamps are connected in parallel. Because of this, there is an advantage that can be used by connecting several lamps in parallel to one inverter. In addition, the external electrode fluorescent lamp has a lower lamp tube wall temperature than the cold cathode fluorescent lamp, thereby significantly eliminating the deterioration of the frame and the color modulation of the screen.

1 is a block diagram of a backlight driving circuit of a conventional liquid crystal display device. As shown in FIG. 1, a backlight voltage is converted into a boosted AC voltage in response to a backlight control signal Vbr-B input from a control device. An inverter 11 outputting to the lamp 12; A backlight lamp 12 which is turned on by the boosted AC voltage output from the inverter 11 and supplies a backlight to the liquid crystal panel 13; A tube current detector 14 which detects a tube current supplied from both ends of the backlight lamp 12 from the inverter 11 and outputs first and second tube current detection signals IS1 and IS2 accordingly; It consists of a protection circuit unit 15 for outputting a shutdown signal to the inverter 11 when the level of the first and second tube current detection signals IS1 and IS2 is below a predetermined value. If described with reference to:

The inverter 11 corresponds to the backlight control signal Vbr-B input from the control device on the system, and converts the DC voltage input from the power supply unit into an AC voltage of a high level suitable for lighting the backlight lamp 12. It outputs to the backlight lamp 12. The backlight control signal Vbr-B is output in the form of a pulse width modulation signal PWM or a DC voltage.

2 shows a waveform diagram of the AC voltage supplied from the inverter 11 to the backlight lamp 12. The inverter 11 adjusts and outputs the duty ratio of the backlight driving signal as shown in FIG. 2 in response to the backlight control signal Vbr-B.

The backlight lamp 12 is turned on by the backlight driving signal shown in FIG. 2 output from the inverter 11, and the brightness thereof is determined by the duty ratio of the backlight driving signal. The light emitted from the backlight lamp 12 which is turned on is supplied to the backlight of the liquid crystal panel 13.

The tube current detector 14 detects a tube current supplied from both ends of the backlight lamp 12 from the inverter 11 and outputs first and second tube current detection signals IS1 and IS2 according to the tube current.

The protection circuit unit 15 outputs a shutdown signal to the inverter 11 when the first and second tube current detection signals IS1 and IS2 fed back from the tube current detection unit 14 are below a predetermined value. The reason for doing this is because it is designed to determine that the normal operation of the backlight lamp 12 is impossible when the level of the feedback first and second tube current detection signals IS1 and IS2 is equal to or less than a predetermined value. to be.

In view of this, the minimum duty ratio of the drive signal output from the inverter 11 to the backlight lamp 12 is designed so as not to fall below 10 to 20%.

As described above, in the inverter driving circuit of the liquid crystal display device, the inverter is shut down by the protection circuit when the tube current of the backlight lamp is below a predetermined value. Therefore, the minimum duty ratio of the driving signal output from the inverter to the backlight lamp is 10 to 10. It is limited to 20%, which makes it difficult to realize a high quality image because the luminance of the backlight cannot be lowered to 0 nit.

Therefore, an object of the present invention is to implement a luminance (0 nit) of the level that the lamp for the backlight is not turned on, while preventing the shutdown of the inverter by the protection circuit.

The present invention for achieving the above object, an inverter for outputting the boosted AC voltage of the duty ratio to the backlight lamp in response to the backlight control signal input from the outside; A tube current detector for detecting a tube current supplied from both ends of the backlight lamp from the inverter and outputting first and second tube current detection signals according to the tube current; A backlight control signal comparing unit comparing the backlight control signal with a first reference voltage and outputting a reference voltage control signal having a same phase according to the backlight control signal; And a protection circuit unit for comparing the first and second tube current detection signals fed back from the tube current detection unit with the second reference voltage controlled by the reference voltage control signal and outputting a shutdown signal to the inverter accordingly. .

When the protection circuit unit compares the tube current detection signal with the reference voltage and outputs the shutdown signal accordingly, the reference voltage is controlled in phase with the backlight control signal, and the backlight control signal is output in the 'high' section. The inverter is shut down when the tube current detection signal is detected to a minimum value below the reference value, and the inverter is prevented from being shut down due to an error or the like in the section in which the backlight control signal is output 'low'. As a result, zero dimming control at a level at which the backlight lamp is not turned on without requiring a striking time is possible, thereby achieving a high quality image.

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

FIG. 3 is a block diagram showing an embodiment of an inverter driving circuit of the liquid crystal display according to the present invention. As shown in FIG. 3, the duty ratio is corresponding to the backlight control signal Vbr-B input from the controller. An inverter 31 for outputting a boosted AC voltage of the inverter; A backlight lamp 32 that is turned on by the boosted AC voltage output from the inverter 31 and supplies a backlight to the liquid crystal panel 33; A tube current detector (34) for detecting a tube current supplied from both ends of the backlight lamp (32) from the inverter (31) and outputting first and second tube current detection signals (IS1) and (IS2) accordingly; A backlight control signal comparison unit 35 for comparing the backlight control signal Vbr-B with a first reference voltage Vref1 and outputting a reference voltage control signal CTL having the same phase accordingly; The first and second tube current detection signals IS1 and IS2 fed back from the tube current detection unit 34 are compared with the second reference voltage Vref2 controlled by the reference voltage control signal CTL, respectively. The protection circuit section 36 outputs the shutdown signal SD when the two tube current detection signals IS1 and IS2 are lower than the second reference voltage Vref2.

The protection circuit unit 36 compares the first tube current detection signal IS1 fed back from the tube current detection unit 34 with the second reference voltage Vref2, and the first tube current detection signal IS1 is the second reference. A first comparator 36A for outputting a shutdown signal SD when the voltage Vref2 is lower than the voltage Vref2; When the second tube current detection signal IS2 fed back from the tube current detector 34 is compared with the second reference voltage Vref2 and the second tube current detection signal IS2 is lower than the second reference voltage Vref2. A second comparing unit 36B for outputting a shutdown signal SD; The reference voltage outputting the power terminal voltage VDD distributed according to the ratio of the resistors R3 and R4 as the second reference voltage Vref2, in synchronization with the phase of the reference voltage control signal CTL. It consisted of the output part 36C.

Referring to Figures 2 and 4 attached to the operation of the present invention configured as described above in detail as follows.

The inverter 31 corresponds to the backlight control signal Vbr-B as shown in FIG. 4A input from the control device on the system, and the DC voltage input from the power supply unit is high enough to turn on the backlight lamp 32. The signal is converted into an AC voltage of the level and outputted to the backlight lamp 32. The backlight control signal Vbr-B is output in the form of a pulse width modulated signal PWM or a DC voltage. Here, the backlight control signal Vbr-B will be described as an example in the form of a pulse width modulated signal PWM.

2 shows a waveform diagram of the AC voltage supplied from the inverter 31 to the backlight lamp 32. The inverter 31 adjusts and outputs the duty ratio of the backlight driving signal as shown in FIG. 2 in response to the backlight control signal Vbr-B.

The backlight lamp 32 is turned on by the backlight driving signal shown in FIG. 2 output from the inverter 31, and the brightness thereof is determined by the duty ratio of the backlight driving signal. Light emitted from the backlight lamp 32 which is turned on is supplied to the backlight of the liquid crystal panel 33.

The tube current detector 34 detects the tube current supplied from the inverter 31 to both ends of the backlight lamp 32, and detects the first and second tube current detection signals IS1 and IS2 as shown in FIG. Output

The comparator CP1 of the backlight control signal comparator 35 compares the backlight control signal Vbr-B, as shown in FIG. 4A, supplied to the inverter 31 with the first reference voltage Vref1. As shown in (b) of FIG. 4, the reference voltage control signal CTL having the same phase is output. That is, the comparator CP1 compares the backlight control signal Vbr-B with the first reference voltage Vref1 and outputs a reference voltage control signal CTL synchronized with the backlight control signal Vbr-B. .

The comparators CP2 and CP3 of the protection circuit unit 36 use the first and second tube current detection signals IS1 and IS2 as shown in FIG. 4C fed back from the tube current detection unit 34 as a second reference. Comparing the voltage Vref2 with each other, the shutdown signal SD as shown in FIG. 4D is output, and the reference voltage control signal CTL whose second reference voltage Vref2 is output from the comparator CP1 is output. Controlled by As a result, the shutdown signal SD output from the comparators CP2 and CP3 is controlled by the reference voltage control signal CTL output from the comparator CP1, and the output process of this shutdown signal SD is performed. The more detailed description is as follows.

First, in FIG. 4, the first section T1 is a maximum dimming section in which the duty ratio of the backlight control signal Vbr-B is input at 100%. In this first section T1, the first lamp T1 is applied to the backlight lamp 33. Since the maximum current flows, the first and second tube current detection signals IS1 and IS2 input from the tube current detection unit 34 are in the form of DC voltage at the maximum level as shown in FIG. In this case, the comparators CP2 and CP3 input the first and second tube current detection signals IS1 and IS2 to the inverting input terminal as shown in FIG. 4C, which is input to the non-inverting input terminal. Compared to the second reference voltage Vref2, the shutdown signal SD having a 'high' level as shown in FIG. 4D is output to the main integrated device 31A of the inverter 31. The main integrated device 31A does not perform a shutdown operation for the inverter 31 when the shutdown signal SD having the 'high' level is input from the comparator CP2 or the comparator CP3 as described above.

In FIG. 4, the second section T2 is an intermediate dimming section in which the duty ratio of the backlight control signal Vbr-B is input at an arbitrary value (eg, 50%) between 0 and 100%. The 'low' section of the backlight control signal Vbr-B as shown in a) or the reference voltage control signal CTL as shown in FIG. 4B is a high voltage alternating current from the inverter 31 to the backlight lamp 32. The voltage is cut off section, and the 'high' section is a section in which the AC voltage of the high voltage is supplied.

Therefore, no tube current flows in the backlight lamp 32 in the 'low' section of the reference voltage control signal CTL, so that the first and second tube current detection signals IS1 and IS2 are low. Is output. At this time, since the reference voltage control signal CTL is output as 'low' from the comparator CP1, the second reference voltage Vref2 is muted to the output terminal of the comparator CP1, and the reference voltage Vref2 is muted. ) Becomes 'low'. Accordingly, a 'low' signal is input to both the non-inverting input terminal and the inverting input terminal of the comparators CP2 and CP3, and at this time, the shutdown signals SD are respectively supplied from the comparators CP2 and CP3. Outputs high.

On the other hand, in the 'high' section of the reference voltage control signal (CTL), the tube current flows through the backlight lamp 32, and thus the first and second tube current detection signals IS1 and IS2 are corresponding to the 'level'. Is output. At this time, since the reference voltage control signal CTL is output as 'high' in the comparator CP1, the power terminal voltage distributed according to the ratio of the resistors R3 and R4 in the reference voltage output unit 36C. VDD is output as the second reference voltage Vref2. Preferably, the second reference voltage Vref2 is set slightly higher than '0'. Accordingly, the comparators CP2 and CP3 have the first and second tube current detection signals IS1 and IS2 of the corresponding level input to the non-inverting input terminal and the second reference voltage input to the inverting input terminal. Compare (Vref2) and output the shutdown signal (SD) 'high' respectively.

When the reference voltage control signal CTL of the third 'high' is output from the comparator CP1 in the second section T2 of FIG. 4, the first and second tube current detection signals IS1 and IS2 are output. An example of detecting a low curent below the reference value is shown, which corresponds to an error such as disconnection of the connector of the backlight lamp 32. In this case, the comparators CP2 and CP3 output the shutdown signal SD as 'low'. Accordingly, the main integrated device 31A takes a shutdown operation on the inverter 31.

The third section T3 of FIG. 4 shows an example of the minimum dimming section in which the duty ratio of the backlight control signal Vbr-B is 0%. At this time, the reference voltage control signal CTL is continuously outputted as 'low' in the comparator CP1, whereby the second reference voltage Vref2 is set as 'low' as described above. Since the backlight lamp 32 is turned off, the first and second tube current detection signals IS1 and IS2 are output as 'low'. Accordingly, the comparators CP2 and CP3 output the shutdown signal SD as 'high'.

First, in the fourth section T4 of FIG. 4, the first and second tube current detection signals IS1 and IS2 are reference values at the maximum dimming section in which the duty ratio of the backlight control signal Vbr-B is input at 100%. The example detected by the following low curent is shown. At this time, since the voltage supplied to the inverting input terminal is higher than the voltage supplied to the non-inverting input terminals of the comparators CP2 and CP3, they output the shutdown signal SD as 'low'. Accordingly, the main integrated device 31A takes a shutdown operation on the inverter 31.

As a result, the comparators CP2 and CP3 receive the first and second tube current detection signals IS1 and IS2 input to the non-inverting input terminal and the second reference voltage Vref2 input to the inverting input terminal. In comparison, in outputting the shutdown signal SD, the second reference voltage Vref2 is controlled as described above by the reference voltage control signal CTL output from the comparator CP1. Accordingly, the first and second tube current detection signals IS1 and IS2 are less than or equal to a reference value in a section in which the backlight control signal Vbr-B or the reference voltage control signal CTL is output as 'high'. The inverter 31 is shut down when detected at a low curent value, and the inverter 31 is shut down due to an error or the like in the section in which the backlight control signal Vbr-B or the reference voltage control signal CTL is output 'low'. Inverter 31 is prevented from shutting down. Accordingly, the dimming control of 10 to 20% as well as the zero dimming control (0 nit) at which the backlight lamp 32 is not lit is possible.

1 is a block diagram of a backlight driving circuit of a conventional liquid crystal display device.

FIG. 2 is a waveform diagram of an AC voltage supplied to the lamp for backlight in FIG. 1. FIG.

3 is a block diagram of an inverter driving circuit of a liquid crystal display device according to the present invention;

(A)-(d) is a waveform diagram of each part of FIG.

*** Description of the symbols for the main parts of the drawings ***

31: inverter 31A: main integrated device

32: backlight lamp 33: liquid crystal panel

34: tube current detector 35: backlight control signal comparison unit

36: protection circuit unit 36A: first comparison unit

36B: second comparison unit 36C: reference voltage output unit

Claims (5)

An inverter configured to output a boosted AC voltage having a duty ratio corresponding to a backlight control signal input from the outside to a backlight lamp; A tube current detector for detecting tube currents supplied from the inverter to both ends of the backlight lamp and outputting first and second tube current detection signals accordingly; A backlight control signal comparing unit comparing the backlight control signal with a first reference voltage and outputting a reference voltage control signal having a same phase according to the backlight control signal; And a protection circuit unit configured to compare the first and second tube current detection signals fed back from the tube current detection unit with the second reference voltage controlled by the reference voltage control signal, respectively, and output a corresponding shutdown signal to the inverter. Inverter drive circuit of the display device. 2. The inverter driving circuit of claim 1, wherein the inverter comprises a main integrated element which shuts down the inverter when the shutdown signal is input at a predetermined level. The inverter driving circuit of claim 1, wherein the tube current detection unit is configured to detect tube currents respectively supplied to both ends of the backlight lamp, and output first and second tube current detection signals accordingly. The comparator of claim 1, wherein the backlight control signal comparator compares the backlight control signal supplied to the non-inverting input terminal with the first reference voltage supplied to the inverting input terminal and outputs a reference voltage control signal having the same phase accordingly. Inverter driving circuit of the liquid crystal display device comprising a. The method of claim 1, wherein the protection circuit unit A first comparing unit which compares the first tube current detection signal fed back from the tube current detector with the second reference voltage and outputs a shutdown signal when the first tube current detection signal is lower than the second reference voltage; A second comparing unit which compares the second tube current detection signal fed back from the tube current detector with the second reference voltage and outputs a shutdown signal when the second tube current detection signal is lower than the second reference voltage; And a reference voltage output unit configured to output a power terminal voltage distributed according to a ratio of two resistors as the second reference voltage, and output in synchronization with a phase of the reference voltage control signal.

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