KR101411721B1 - Device of driving backlight unit and driving method therof - Google Patents

Abstract

A backlight unit driving apparatus of the present invention includes a lamp control unit for outputting a PWM signal having a duty ratio varied according to a rated modulation signal, a switch unit for outputting an input voltage in accordance with the PWM signal, A lamp control unit for controlling the lamp in accordance with the rated modulating signal; a lamp control unit for controlling the lamp in accordance with the rated modulating signal; An input voltage detection unit for generating a signal determined by the signal detected from the input voltage and the output signal of the rating modulation unit; DC converter that increases the output voltage by a predetermined voltage.

 Backlight unit, rated modulation unit, tube current

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a backlight unit driving apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a backlight, and more particularly, to a backlight driving apparatus and a driving method thereof capable of improving image quality.

As the information society develops, the demand for display devices is increasing in various forms. In recent years, various flat panel display devices including a liquid crystal display device (LCD), a plasma display panel (PDP), and an electro luminescent display (ELD) have been studied. Has already been widely used as a display device.

Among these, the liquid crystal display device is excellent in the current image quality, and has advantages such as light weight, thinness, and low power consumption, thereby quickly replacing the CRT. 2. Description of the Related Art Liquid crystal display devices have been developed variously as monitors for notebook computers, display panels for televisions, and the like.

Since a liquid crystal display device can not emit light by itself, a light source such as a backlight unit is required. In a liquid crystal display, light emitted from a backlight unit is transmitted / interrupted according to displacement of a liquid crystal of a liquid crystal panel, thereby displaying an image.

1 is a view showing a conventional backlight unit driving apparatus.

1, a conventional backlight unit driving apparatus includes a lamp control unit 101, a DC-DC converter 103, a switch unit 105, a transformer 107, a lamp 109, a lamp output detecting unit 111 And an input voltage detecting unit 113. [

The switch unit 105 outputs the input voltage supplied from the DC-DC converter 103 in accordance with the PWM signal supplied from the lamp control unit 101.

The transformer 107 boosts the input voltage supplied from the switch unit 105 to generate a driving voltage, and the lamp 109 is driven by the driving voltage to emit light.

The lamp output detecting unit 111 detects an output signal of the lamp 109 and supplies the detected signal to the lamp control unit 101. The lamp control unit 101 controls the switch unit 105 based on the signal supplied from the lamp output detecting unit 111, And supplies the generated PWM signal.

The lamp 109 is driven by the driving voltage supplied by the transformer 107 and a tube current flows in the lamp 109 at this time. The luminance of the lamp 109 is determined by the tube current.

Therefore, the tube current must be increased to increase the luminance. The tube current is determined by the driving voltage supplied to the lamp 109, and this driving voltage is determined by the output voltage output from the switch unit 105. [ This output voltage can be adjusted by the PWM signal supplied from the lamp control unit 101. [ That is, if the duty ratio of the PWM signal is increased, the width of the output voltage generated by the input voltage at the switch unit 105 is increased, and the drive voltage generated by the transformer 107 is increased by the output voltage So that the tube current of the lamp 109 also increases.

However, there is a limit to increase the duty ratio of the PWM signal generated by the lamp control unit 101. [ That is, the duty ratio of the PWM signal can be limited up to 50%. In other words, when the duty ratio of the PWM signal is 50%, the switch unit 105 directly outputs the input voltage as the output voltage by the PWM signal.

Normally, the case where the duty ratio of the PWM signal is the maximum is set to the rated value of the tube current.

On the other hand, when a moving picture is displayed on a liquid crystal display device, a bright part is sometimes required to be displayed in a brighter state. For example, sunlight or a strong neon sign should be displayed brighter and the picture quality may be clearer. Therefore, the higher the contrast ratio, the better the picture quality. In the conventional backlight driving apparatus, since the rated tube current is already set, there is a limit in generating the tube current of the rated value or more.

Accordingly, the present invention relates to a backlight unit driving device and a driving method thereof that can generate a tube current equal to or higher than the rated current and improve the image quality as the contrast ratio increases.

According to a first embodiment of the present invention, a backlight unit driving apparatus includes: a lamp controller for outputting a PWM signal having a duty ratio varied according to a rated modulation signal; A switch unit for outputting an input voltage according to the PWM signal; A transformer for boosting an output signal output from the switch unit to generate a driving voltage; A lamp for emitting light according to the driving voltage; A lamp output detector for detecting an output of the lamp; A rated modulating section for modulating the rating of the tube current of the lamp; A switch for switching the connection between the rated modulation section and the lamp output detection section according to the rated modulation signal; An input voltage detector for generating a signal detected from the input voltage and a signal determined by an output signal of the rated modulator; And a DC-DC converter for increasing the input voltage by a predetermined voltage based on a signal determined by the input voltage detector.

According to a second aspect of the present invention, there is provided a method of driving a backlight unit, comprising: generating a PWM signal having a duty ratio varied according to a rated modulation signal in a lamp control unit; Outputting an input voltage in accordance with the PWM signal in a switch unit; Boosting the output signal in a transformer to generate a driving voltage; Emitting light from the lamp according to the driving voltage; Detecting an output of the lamp at a lamp output detecting unit; Modulating the rating of the tube current of the lamp at the rated modulation section; Switching the connection between the rated modulating part and the lamp output detecting part according to the rated modulating signal; Generating a signal detected from the input voltage and a signal determined by an output signal of the rated modulating unit in an input voltage detecting unit; And increasing the input voltage by a predetermined voltage based on a signal determined from the input voltage detector in the DC-DC converter.

According to the present invention, when a tube current equal to or higher than the rated value is required, the input voltage supplied to the switch section is increased by the signal modulated by the rated modulating section to generate the tube current of the lamp at or above the rated value, thereby increasing the contrast ratio .

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

2 is a diagram illustrating a backlight unit driving apparatus according to the present invention.

2, the backlight unit driving apparatus includes a lamp control unit 11, a DC-DC converter 13, a switch unit 15, a transformer 17, a lamp 19, a lamp output detecting unit 21, 22, a rated modulating section 23, and an input voltage detecting section 25. [

The lamp control unit 11 generates a PWM signal and supplies the generated PWM signal to the switch unit 15. The PWM signal is a signal having an on / off period repeatedly. The lamp control unit 11 can modulate the PWM signal based on the signal detected from the lamp output detecting unit 21. That is, when the tube current of the lamp 19 is lower than the desired tube current, the duty ratio of the PWM signal can be increased and supplied to the switch unit 15. The driving voltage generated via the switch unit 15 and the transformer 17 is increased by the PWM signal whose duty ratio is increased as described above, so that the tube current of the lamp 19 is increased, and a desired tube current can be obtained.

The switch unit 15 may include four FET switches arranged in the form of a bridge. The output voltages in opposite directions to each other are alternately supplied to the transformer 17 by the four FET switches. Each FET switch can be controlled by a PWM signal supplied from the lamp control unit 11. [ That is, the FET switch is turned on and the input voltage is outputted during the ON period of the PWM signal supplied from the lamp controller 11, and the FET switch is turned off during the OFF period of the PWM signal supplied from the lamp controller 11, The voltage is not outputted. The input voltage is a voltage supplied from the DC-DC converter 13. Therefore, the output voltage supplied from the switch unit 15 has a rectangular wave form in which on / off intervals are repeated. The input voltage may be a DC voltage having a constant level.

The transformer 17 boosts the output voltage supplied from the switch unit 15 by a predetermined multiple and supplies the generated driving voltage to the lamp 19. [ The drainage may be determined by adjusting the turns ratio of the primary coil and the secondary coil of the transformer 17.

The lamp 19 is driven by the driving voltage to cause a tube current to flow therein and emit light of a luminance corresponding to the tube current.

The lamp output detecting unit 21 is provided at an output terminal of the lamp 19. The lamp output detector 21 detects the tube current of the lamp 19. That is, the lamp output detecting unit 21 detects a tube current of the lamp 19 and outputs a signal (e.g., voltage or current) corresponding to the tube current to the lamp control unit 11 and / or the rated modulation unit 23 Output.

The switch 22 is provided between the lamp output detecting unit 21 and the rated modulating unit 23. The output signal of the lamp output detecting unit 21 is supplied to the lamp control unit 11 or the rated modulation unit 23 according to the selection of the switch 22. [ That is, when the switch 22 is in the off state, the output signal of the lamp output detecting unit 21 is supplied only to the lamp control unit 11. The output signal of the lamp output detecting unit 21 can be supplied to the rated modulating unit 23 via the switch 22 as well as the lamp control unit 11 when the switch 22 is on. The switch 22 may be switched according to a rated modulation signal supplied from an external device (e.g., a system or a timing controller).

The rated modulation signal can be generated in response to an event (whether or not the rated modulation is generated) occurring externally. For example, when the rated modulation is not performed, the rated modulation signal may be supplied to the switch 22 by '0'. In this case, the switch 22 is turned off, so that the output signal of the lamp output detecting unit 21 can be supplied to the lamp control unit 11. In the case of performing the rated modulation, the rated modulation signal may be supplied to the switch 22 by '1'. In this case, the switch 22 is turned on, so that the output signal of the lamp output detecting unit 21 can be supplied to the lamp control unit 11 and the rated modulation unit 23.

On the other hand, when the rated modulation signal is '0', the lamp control unit 11 generates a PWM signal based on the output signal of the lamp output detecting unit 21 in a normal manner and supplies the PWM signal to the switch unit 15. However, when the rated modulation signal is '1', the lamp control unit 11 must generate the tube current of the lamp 19 at the rated value or more, so that the duty ratio of the PWM signal is set to the maximum (50% ). As described above, since the rated tube current can be obtained when the duty ratio of the PWM signal is maximized, a tube current not yet rated can not be obtained.

In the present invention, in order to obtain a tube current equal to or higher than the rated value, first, the rated tube current is obtained by maximizing the duty ratio of the PWM signal, and the tube current is obtained by increasing the input voltage of the DC-DC converter 13 through the rated modulation .

Hereinafter, the technical features of the present invention will be described in detail.

The lamp control unit 11 supplies the PWM signal having the maximum duty ratio to the switch unit 15 while the switch 22 is turned on and the lamp control unit 11 The output signal is supplied to the rated modulation section 23. [

The rated modulating section 23 may be a calculator 23a capable of comparison and amplification as shown in FIG. The calculator 23a receives the output signal of the lamp output detector 21 and the reference voltage, compares the output signal with the reference voltage, amplifies the difference, and outputs the amplified difference. The reference voltage may vary depending on the degree of the tube current above the rated value. For example, if the rated tube current is 30 mA, and the tube current is 50 mA, 60 mA, or 70 mA or more, the reference voltage must also be varied to obtain the tube currents above the rated value. Therefore, each reference voltage is set so as to correspond to the tube current of each rating or higher, and this reference voltage can be varied by a user or the like.

The comparison amplification signal output from the nominal modulation section 23 may be supplied to the input voltage detection section 25. [ As shown in FIG. 4, the input voltage detector 25 may include first to third resistors R1 to R3. The first resistor R1 is connected between the output terminal O of the DC-DC converter 13 and the feedback terminal F and the second resistor R2 is connected between the feedback terminal F of the DC- And the third resistor R3 may be connected in parallel between the first and second resistors R1 and R2 and may be connected to the rating modulator 23. [

When the comparison amplification signal is not supplied to the input voltage detecting unit in the rated modulating unit 23, the input voltage is detected from the input voltage by the voltage division by the first and second resistors R1 and R2 of the input voltage detecting unit 25 And the divided voltage can be supplied to the DC-DC converter 13 through the feedback stage F. [ The DC-DC converter 13 determines whether to adjust the input voltage based on the voltage supplied to the feedback stage F, and adjusts the input voltage based on the determined signal to output the adjusted output voltage. The input voltage detector 25 is provided to stabilize the input voltage output from the DC-DC converter 13, and the DC-DC converter 13 detects the input voltage detected by the input voltage detector 25 Adjust it to the desired input voltage.

The input voltage detecting unit 25 of the present invention further includes a third resistor R3 connected to the rated modulating unit 23 so that the comparison amplified signal supplied from the rated modulating unit 23 is supplied to the detected signal from the input voltage Reflect. That is, the input voltage detecting unit 25 not only detects the input voltage but also receives the comparison amplified signal supplied from the rating modulating unit 23, and the signal determined by the detected input voltage and the detected comparison amplified signal is supplied to the DC- Is input to the feedback terminal (F) of the converter (13).

The DC-DC converter 13 raises the input voltage by a predetermined voltage based on the determined signal. The predetermined voltage may be preset according to the determined signal. For example, when the input voltage is 5 V and the determined signal is 5.4 V and the signal supplied to the DC-DC converter 13 from the input voltage detecting unit 25 is 2 V in the case of the rated voltage, In case of rated at 5.4V, 3.4V can be obtained by subtracting 2V from the input signal. Therefore, the input voltage may be 8.4 V, which is increased by 3.4 V to 5 V, which is a base input voltage.

The increased input voltage (8.4V) is supplied to the switch unit 15 and is then switched, boosted by the transformer 17, and supplied to the lamp 19 at a voltage higher than the drive voltage at the time of rated drive. Therefore, a further increased tube current flows through the lamp 19 to obtain a tube current higher than the rated tube current, and thus a further increased luminance can be obtained. Therefore, the image can be displayed with a further increased contrast ratio in the liquid crystal display device by the lamp 19 thus emitted, and the image quality can be improved.

In addition, since the present invention can obtain a tube current equal to or higher than the rated current, the adjustment range of the tube current can be expanded, and the range of the peak luminance can be expanded.

As shown in FIG. 5, the present invention supplies an input voltage, which is further increased at the time of rated driving or more, to the switch unit 15 and supplies the input voltage to the lamp unit 15 via the switch unit 15 and the transformer 17 19 by supplying a further increased driving voltage to the lamp 19. [

6 is a flowchart illustrating a method of driving a backlight unit according to the present invention.

Referring to FIGS. 1 and 6, a rated modulation signal is supplied from an external (system or timing controller) (S 51). The rated modulation signal may be either '0' or '1'. When the rated modulation signal is "0", it means driving the lamp 19 in the conventional manner, that is, driving the lamp 19 with the rated tube current. When the rated modulation signal is '1', it means that the lamp 19 is driven with a tube current equal to or higher than the rated current. The rated modulation signal can be generated by the user or system in response to the event.

Based on the rated modulation signal, it is determined whether or not the drive is rated or higher (S 53). This can be determined from whether the rated modulation signal is '0' or '1'.

When the rated modulation signal is '0', the lamp control unit 11 generates a PWM signal having a constant duty ratio based on the rated modulation signal (S 55). The constant duty ratio may be preset for rated drive. At the same time, since the switch 22 is turned off by the rated modulation signal having '0', the output signal of the lamp output detecting unit 21 can be supplied only to the lamp control unit 11.

Thereafter, a driving voltage can be generated via S 59 to S 61.

That is, the switch unit 15 supplies the input voltage to the output voltage according to the constant duty ratio supplied from the lamp control unit 11 (S 59). Accordingly, the input voltage may be a DC voltage having a constant level, while the output voltage may have a square wave form having an on / off period according to the constant duty ratio.

The transformer 17 boosts the rectangular-wave output voltage to generate a sine-wave-like driving voltage having an AC voltage (S61).

The lamp 19 is driven by the driving voltage to emit light having luminance corresponding to the tube current flowing in the lamp 19 (S63).

The output of the lamp 19 is detected by the lamp output detecting unit 21 provided at the output terminal of the lamp 19 and outputted as a constant signal (voltage or current) (S65).

The signal detected by the lamp output detection unit 21 is supplied to the lamp control unit 11, and the lamp control unit 11 adjusts and outputs the PWM signal based on the detected signal. This is to stabilize the instability of the tube current of the lamp 19 during the initial driving.

In this way, when the lamp 19 is driven at a rated speed, the input voltage is outputted in accordance with the PWM signal generated by the lamp control unit 11, and the output voltage is boosted to supply the lamp 19 with the driving voltage So that the lamp 19 is driven at rated speed.

On the other hand, when the rated modulation signal is '1', the lamp controller 11 adjusts the PWM signal to the maximum duty ratio and outputs the PWM signal having the maximum duty ratio (S 57).

At the same time, the switch 22 is turned on by the rated modulating signal having the value '1', so that the lamp output detecting unit 21 and the rated modulating unit 23 are switched to be connected (S 67). Therefore, the output signal of the lamp output control section can be supplied to the rated modulation section 23.

The rated modulation unit 23 compares the output signal of the lamp output modulation unit with a reference voltage to amplify a difference value between the output signal and the reference voltage (S 69).

The amplified signal is supplied to an input voltage detecting unit 25. The input voltage detecting unit 25 detects the input voltage and receives the amplified signal from the rating modulating unit 23, And supplies the determined signal to the DC-DC converter 13 (S71).

The DC-DC converter 13 increases the input voltage by a predetermined voltage based on the determined signal supplied from the input voltage detector 25 (S 73). The predetermined voltage may be a difference value between the determined signal and a signal detected by the input voltage detecting unit 25 at the time of the rated driving. For example, when the determined signal is 5.4 V and the signal detected by the input voltage detector 25 at the time of rated driving is 2 V, the constant voltage may be 3.4 V. Therefore, the input voltage (8.4V) may be increased by the constant voltage by reflecting the constant voltage (3.4V) to the base input voltage (5V).

The switch unit 15 modulates and outputs the increased input voltage (8.4V) according to a PWM signal having a maximum duty ratio, and the output voltage is boosted by the transformer 17 so that the drive voltage is applied to the ramp 19, So that the lamp 19 emits light with a tube current equal to or higher than the rated current.

1 is a view showing a conventional backlight unit driving apparatus.

2 is a view illustrating a backlight unit driving apparatus according to the present invention.

3 is a circuit diagram showing the rated modulation of FIG.

4 is a circuit diagram showing the output voltage detecting unit of Fig.

Figure 5 illustrates the input voltage variation of the present invention.

6 is a flowchart for explaining a backlight unit driving method according to the present invention

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

11: Lamp control unit 13: DC-DC converter

15: Switch part 17: Transformer

19: Lamp 21: Lamp output detecting section

22: switch 23: rated modulation section

23a: Operator 25: Input voltage detector

Claims (13)

A lamp controller for outputting a PWM signal having a duty ratio varied according to a rated modulation signal; A switch unit for outputting an input voltage according to the PWM signal; A transformer for boosting an output signal output from the switch unit to generate a driving voltage; A lamp for emitting light according to the driving voltage; A lamp output detector for detecting an output of the lamp; A rated modulating section for modulating the rating of the tube current of the lamp; A switch for switching the connection between the rated modulation section and the lamp output detection section according to the rated modulation signal; An input voltage detector for generating a signal detected from the input voltage and a signal determined by an output signal of the rated modulator; And And a DC-DC converter for increasing the input voltage by a predetermined voltage based on a signal determined by the input voltage detecting unit. 2. The backlight unit driving apparatus according to claim 1, wherein the rated modulation signal includes a signal for rated driving and a signal for driving at least rated. 3. The backlight unit driving apparatus of claim 2, wherein the switch is switched to connect the lamp output detecting unit and the rated modulation unit according to a signal for driving at least the rating. The backlight unit driving apparatus according to claim 2, wherein the lamp control unit generates a PWM signal having a maximum duty ratio according to a signal for driving at least the rated current. 2. The backlight unit driving apparatus according to claim 1, wherein the rated modulating unit is a calculator for comparison and amplification. 6. The backlight unit driving apparatus of claim 5, wherein the arithmetic unit compares an output signal of the lamp output detection unit with a reference voltage and amplifies the difference value. The backlight unit driving apparatus according to claim 6, wherein the reference voltage is varied according to a driving degree of the rated voltage. 2. The backlight unit driving apparatus according to claim 1, wherein the predetermined voltage is a difference value between the determined signal and a signal detected by the input voltage detecting unit at the time of the rated driving. Generating a PWM signal having a variable duty ratio in accordance with a rated modulation signal in a lamp control unit; Outputting an input voltage in accordance with the PWM signal in a switch unit; Boosting the output signal in a transformer to generate a driving voltage; Emitting light from the lamp according to the driving voltage; Detecting an output of the lamp at a lamp output detecting unit; Modulating the rating of the tube current of the lamp at the rated modulation section; Switching the connection between the rated modulating part and the lamp output detecting part according to the rated modulating signal; Generating a signal detected from the input voltage and a signal determined by an output signal of the rated modulating unit in an input voltage detecting unit; And And increasing the input voltage by a predetermined voltage based on a signal determined from the input voltage detection unit in the DC-DC converter. 10. The driving method of claim 9, wherein the rated modulation signal includes a signal for a rated driving and a signal for driving a rated driving or more. The driving method of a backlight unit according to claim 10, wherein the lamp output detection unit is switched to connect the rated modulation unit according to a signal for driving the rated or higher. The driving method of a backlight unit according to claim 10, wherein a PWM signal having a maximum duty ratio is generated according to a signal for driving at least the rated current. The driving method of a backlight unit according to claim 9, wherein the constant voltage is a difference value between the determined signal and a signal detected by the input voltage detecting unit at the time of the rated driving.

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