KR20110139499A - Lcd and method of driving the same - Google Patents

Abstract

PURPOSE: A liquid crystal display device and a driving method thereof are provided to suppress an in-rush phenomenon of a current inputted to a DC-DC converter by controlling an output voltage generated from the DC-DC converter before an LED lamp is turned on or off. CONSTITUTION: A backlight includes a plurality of LED lamp arrays composed of a plurality of LED lamps which provide light to a liquid crystal panel. A lamp driving unit applies an output voltage to the backlight and includes a DC-DC converter, a feedback voltage generator(520), and a PWM control unit. The feedback voltage generator generates a feedback voltage by estimating the on and off of the LED lamp according to a PWM control signal in advance. A DC-DC converter(510) generates an output voltage corresponding to the feedback voltage.

Description

Liquid crystal display and its driving method {LCD and method of driving the same}

The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device for stably supplying an output voltage generated by a DC-DC converter of a liquid crystal display device to an LED lamp.

As the information society develops, the demand for display devices for displaying images is increasing in various forms. Recently, liquid crystal displays (LCDs), plasma display panels (PDPs), organic fields Various flat display devices such as organic light emitting diodes (OLEDs) are being utilized.

Among these flat panel display devices, liquid crystal display devices are widely used because they have advantages of miniaturization, light weight, thinness, and low power driving. On the other hand, an active matrix type liquid crystal display device in which a plurality of pixels are arranged in a matrix form and a switching transistor is formed in each of these pixels is currently widely used.

The backlight of the liquid crystal display device is mainly a cold cathode fluorescent lamp (CCLF) type using a fluorescent tube, but environmentally friendly use of mercury has been required. For this reason, recently, a light emitting diode (LED) lamp is promising as a light source.

1 is a view schematically showing a lamp driving unit of a conventional LED lamp.

The conventional lamp driver 50 includes a DC-DC converter 51 and a feedback voltage generator 52.

However, when using the LED lamp as a backlight, as shown in Figure 2, due to the sudden change in the output current (Iout) when the LED lamp on-off, inrush (rush) and output voltage of the input current (Iin) (Vout) Dropping phenomenon occurs.

As shown in FIG. 1, in the conventional lamp driver 50, the output voltage Vout generated by the DC-DC converter 51 is output to the LED lamp without additional pretreatment. There is a problem in that the inrush and the drop of the output voltage Vout cannot be suppressed.

The present invention controls the output voltage generated in the DC-DC converter before the on-off operation of the LED lamp. Accordingly, an object of the present invention is to provide a liquid crystal display and a driving method thereof, which can improve an output voltage drop and an input current inrush phenomenon caused by a sudden change in the output current of an LED lamp.

In order to achieve the above object, the present invention is a liquid crystal panel; A backlight including a plurality of LED lamp arrays comprising a plurality of LED lamps providing light to the liquid crystal panel; And a lamp driver for applying an output voltage to the backlight, wherein the lamp driver includes a DC-DC converter, a feedback voltage generator, and a PWM controller, wherein the feedback voltage generator is a PWM control input from the PWM controller. According to a signal, the LED lamp is predicted on and off in advance, and generates a feedback voltage, and the DC-DC converter provides an LCD that generates an output voltage corresponding to the feedback voltage.

The feedback voltage generation unit includes an on-off prediction unit that receives the PWM control signal from the PWM control unit before the FET for a predetermined time and generates an on-off expected signal in response thereto.

The apparatus further includes a max voltage detector configured to detect a max voltage among forward voltages of the plurality of LED lamp arrays, and the feedback voltage generator includes a feedback voltage controller configured to receive the max voltage and generate the feedback voltage corresponding thereto. do.

Lamp including a plurality of LED lamp array consisting of a plurality of LED lamps for providing light to the liquid crystal panel, a DC-DC converter, a feedback voltage generator, a PWM control unit for applying an output voltage to the backlight A driving method of a liquid crystal display device comprising a driving unit, the feedback voltage generating unit generating a feedback voltage by predicting on / off of the LED lamp in advance according to a PWM control signal input from the PWM control unit; ; In the DC-DC converter, a method of driving the liquid crystal display device comprising generating the output voltage corresponding to the feedback voltage.

The feedback voltage generation unit may further include receiving the PWM control signal from the PWM control unit before the FET for a predetermined time and generating an on-off expected signal in response thereto.

Detecting a max voltage among forward voltages of the plurality of LED lamp arrays; The generating of the feedback voltage may further include generating the feedback voltage corresponding to the max voltage.

The liquid crystal display according to the present invention has the effect of generating a stable LED lamp driving voltage by controlling the output voltage generated in advance in the DC-DC converter before the LED lamp on-off is operated. In addition, the inrush phenomenon of the current input to the DC-DC converter can also be suppressed.

Accordingly, the noise problem of the DC-DC converter is eliminated.

1 is a view schematically showing a lamp driving unit of a conventional LED lamp.
2 is a view schematically showing the inrush of the output current and the drop of the output voltage when driving a conventional LED lamp.
3 is a schematic view of a liquid crystal display device according to an embodiment of the present invention;
4 is an equivalent circuit diagram of a pixel according to an embodiment of the present invention.
5 is a view schematically showing a lamp driver according to an embodiment of the present invention.
6 is a timing diagram schematically showing an output current and an output voltage according to an embodiment of the present invention.
FIG. 7 schematically shows the impedance and impedance distribution of an LED lamp according to temperature and current. FIG.

Hereinafter, with reference to the drawings will be described an embodiment of the present invention.

3 is a view schematically showing a liquid crystal display device according to an embodiment of the present invention, and FIG. 4 is an equivalent circuit diagram schematically showing pixels of a liquid crystal panel according to an embodiment of the present invention.

As illustrated, the liquid crystal display device 100 according to the embodiment of the present invention includes a liquid crystal panel 200, a backlight 400, and a driver.

The liquid crystal panel 200 includes two substrates facing each other, for example, an array substrate AS and an opposite substrate OS, and a liquid crystal layer positioned between the two substrates.

In the array substrate AS of the liquid crystal panel 200, a plurality of gate lines GL extending in a first direction and a plurality of data lines DL extending in a second direction cross each other to form a matrix. A plurality of pixels P arranged in the form of) is defined.

Referring to FIG. 4, in each pixel P, a switching transistor T connected to the gate line and the data line GL and DL is formed. The switching transistor T is connected to the pixel electrode. Meanwhile, a common electrode is formed corresponding to the pixel electrode, and when voltage is applied to the pixel electrode and the common electrode, an electric field is formed between them to drive the liquid crystal. The pixel electrode, the common electrode, and the liquid crystal positioned between these electrodes constitute a liquid crystal capacitor Clc. Meanwhile, a storage capacitor Cst is further configured in each pixel P, which stores a data voltage applied to the pixel electrode until the next frame.

The backlight 400 serves to supply light to the liquid crystal panel 200. In the embodiment of the present invention, as the backlight 400, a plurality of LED lamps can be used.

Here, in the case of a backlight in which the LED lamp is used, since the size of the light is adjusted in accordance with the amount of current flowing through the LED lamp, for example, the DC voltage Vin supplied from the power generation unit 320 is LED. It includes a DC-DC converter which converts the output voltage Vout, which is a bias voltage of, and supplies it to the electrode of the lamp (this will be described in more detail later).

The driver may include a timing controller 310, a power generator 320, a gate driver 330, a data driver 340, and a lamp driver 500.

Here, the timing controller 310 inputs a video data signal RGB, a vertical synchronization signal, a horizontal synchronization signal, a clock signal, and a data enable signal TCS from an external system such as a TV system or a video card. Will receive. Although not shown, such signals may be input through an interface configured in the timing controller 310.

The timing controller 310 generates a gate control signal GCS for controlling the gate driver 330 and a data control signal DCS for controlling the data driver 340 using the input control signal TCS. do. The gate control signal GCS includes a gate start pulse (GSP), a gate shift clock (GSC), a gate output enable signal (GOE), and the like. The data control signal (DCS) includes a source start pulse (SSP), a source shift clock (SSC), a source output enable signal (SOE), and a polarity signal (POL). And the like.

In addition, the timing controller 310 receives image data RGB from an external system, arranges the image data RGB, and transmits the image data RGB to the data driver 340.

The power generation unit 320 generates various driving voltages necessary for driving the liquid crystal display device 100. For example, the power supply voltage supplied to the timing controller 310, the data driver 340, the gate driver 330, and the lamp driver 500, the gate high voltage and the gate low voltage supplied to the gate driver 330. Will generate

The data driver 340 supplies the data voltage to the plurality of data wirings DL in response to the data control signal DCS and the image data RGB supplied from the timing controller 310. That is, the gamma reference voltage is used to generate a data voltage corresponding to the image data RGB, and output the generated data voltage to the data wiring DL.

The gate driver 330 sequentially scans the plurality of gate lines GL in response to the gate control signal GCS supplied from the timing controller 310. For example, a plurality of gate lines GL are sequentially selected during each frame, and a gate voltage is output to the selected gate lines GL. By the gate voltage, the switching thin film transistor T positioned in the corresponding row line is turned on. On the other hand, the turn-off voltage is supplied to the gate line GL until the next frame is scanned, so that the switching thin film transistor T is maintained in the turn-off state.

The gate driver 330 may be manufactured in an IC form and connected to the liquid crystal panel 200, or may be directly formed on the liquid crystal panel 200. The method in which the gate driver 330 is directly formed in the liquid crystal panel 200 is called a GIP (Gate In Panel) method. In such a GIP method, in the process of forming an array element including the switching thin film transistor T, the gate wiring GL, and the data wiring DL on the liquid crystal panel 200, the gate driver 330 may be a liquid crystal panel ( 200) can be formed directly.

The lamp driver 500 receives a DC voltage Vin from the power generator 320, converts it into an output voltage Vout which is a bias voltage for driving the LED, and supplies the same to the backlight 400.

Hereinafter, the lamp driving unit 500 according to the embodiment of the present invention will be described in more detail with reference to FIGS. 5 and 6.

5 is a view schematically illustrating a lamp driver 500 and a backlight 400 according to an embodiment of the present invention, and FIG. 6 is an output voltage Vout and a feedback voltage FB according to an embodiment of the present invention. A timing diagram schematically showing the relationship between

First, the lamp driver 500 and the backlight 400 according to the exemplary embodiment of the present invention will be described with reference to FIG. 5.

As shown in FIG. 5, the backlight 400 may include a plurality of LED lamps. In this case, the plurality of LED lamps are connected in series to form one LED lamp array 410, the plurality of LED lamp array 410 forms a backlight 400.

The anode side of the LED lamp array 410 connected in series is connected to the output terminal of the output voltage Vout of the DC-DC converter 510 via a constant resistance (not shown). The cathode side of the LED lamp array 410 connected in series is connected to the max voltage detection unit 530. The cathode side of the LED lamp array 410 is grounded via the source-drain of the FET 550.

Hereinafter, the lamp driver 500 will be described in more detail.

As shown, the lamp driver 500 according to the embodiment of the present invention, the DC-DC converter 510, the feedback voltage generation unit 520, the max voltage detection unit 530, PWM control unit 540 And the FET 550. In addition, the feedback voltage generator 520 according to the exemplary embodiment of the present invention may include a feedback voltage controller 521 and an on-off predictor 522.

The DC-DC converter 510 receives a DC voltage Vin generated from the power generator 320 and switches the input DC voltage Vin to generate a stabilized DC output voltage Vout. In addition, the DC-DC converter 510 receives the feedback voltage FB generated by the feedback voltage generator 520 and generates a stabilized output voltage Vout in response thereto.

As shown in FIG. 6, when the feedback voltage FB has a negative value smaller than the preset reference voltage, the output voltage Vout is increased and the feedback voltage FB is the preset reference voltage. In the case of having a larger positive value, the output voltage Vout decreases. In addition, the change amount of the feedback voltage FB and the change amount of the output voltage Vout are proportional.

Here, the feedback voltage FB is influenced by the voltage actually applied to the LED lamp array 410. That is, it is generated in response to a voltage (hereinafter, referred to as a forward voltage Vf) of the sum of the voltages VLED actually applied to the plurality of LED lamps constituting one LED lamp array 410. The feedback voltage FB will be described later in more detail.

At this time, the current (ILED) flowing through the LED lamp is changed according to the characteristics of the LED lamp and the temperature of the LED lamp, and accordingly the voltage actually applied to the LED lamp array 410, that is, the forward voltage (Vf) is also different feedback The voltage FB will also vary. That is, as shown in FIG. 7, as the temperature of the lamp increases, the impedance and impedance distribution of the lamp tend to decrease. In addition, as the current flowing through the lamp increases, the impedance and impedance distribution of the lamp decrease. Therefore, the value of the forward voltage Vf is changed.

The max voltage detector 530 detects max voltages MVf of the LED lamp arrays 410. In addition, the detected max voltage MVf is output to the feedback voltage generation unit 520.

Here, the max voltage MVf is the forward voltage Vf having the highest value among the forward voltages Vf applied to the LED lamps 410.

As described above, the forward voltage Vf is a voltage actually applied to the LED lamp array 410. That is, it means a voltage applied from the anode direction of the LED lamp to the cathode direction. Due to the characteristics of the LED lamp, such as temperature, the current (ILED) and the voltage (VLED) applied to each of the LED lamps are different. Accordingly, the forward voltage Vf flowing through the plurality of LED lamp arrays 410 also varies.

Accordingly, in order to drive all the LED lamps of the backlight 400, the output voltage Vout must be generated in the DC-DC converter 510 based on the highest forward voltage Vf, that is, the max voltage MVf. do.

In addition, the output voltage Vout generated by the DC-DC converter 510 is generated in response to the feedback voltage FB. Therefore, in order to generate the stable output voltage Vout by reflecting the max voltage MVf at the time of generating the feedback voltage FB, the max voltage MVf is detected.

The PWM controller 540 generates a PWM control signal PS, and outputs the PWM control signal PS to the FET 550 and the feedback voltage generator 520. Here, the PWM control signal PS is output to the on-off predictor 521 of the feedback voltage generator 520.

At this time, the PWM controller 540 first outputs the PWM control signal PS to the on-off predictor 521 of the feedback voltage generator 520, and then outputs the PWM control signal PS to the FET 550 after a predetermined time.

Here, PWM control signal PS is a square wave signal which adjusts the duty ratio of the on time and off time of an LED lamp. Therefore, according to the on-off duty width of the PWM control signal PS, the emission time and the amount of current of the LED lamp flowing through the LED lamp are adjusted. Specifically, for example, the duty width when the PWM control signal PS is on is increased to increase the current and light emission time flowing into the LED lamp, and the duty width when the PWM control signal PS is on is reduced to the LED. Reduce the current and the light emitting time flowing into the lamp.

The PWM control signal PS generated by the PWM controller 540 is output to, for example, the on-off predictor 521 and then to the FET 550 after a predetermined time.

This is to adjust the feedback voltage FB in anticipation of whether the LED lamp is driven in the on-off predicting unit 521 in advance. This will be described in more detail later.

The FET 550 receives the PWM control signal PS generated by the PWM controller 540 through the gate of the FET 550. In this case, after the PWM control signal PS is output to the on-off predictor 522 of the feedback voltage generator 520, the PWM control signal PS is output to the FET 550 after a predetermined time as described above.

The FET 550 is turned on when the PWM control signal PS is on, and is turned off when the PWM control signal PS is off. Therefore, the FET 550 flows current to the LED lamp when the PWM control signal PS is on, and turns off the current flowing to the LED lamp when the PWM control signal PS is off. That is, the FET 550 causes the LED lamp to emit light when the PWM control signal PS is on, and the LED lamp not emits light when the PWM control signal PS is off.

The feedback voltage generator 520 receives the PWM control signal PS from the PWM controller 530, anticipates the on / off of the LED lamp in advance, generates the feedback voltage FB, and generates the generated feedback voltage FB. ) Is output to the DC-DC converter 510.

At this time, when generating the feedback voltage FB, the max voltage MVf is input from the max voltage detector 530 to generate a feedback voltage FB corresponding thereto. That is, the max voltage MVf is input from the max voltage detection unit 530 and the PWM control signal PS is input from the PWM control unit 530, and in response thereto, the feedback voltage FB is generated. In addition, the generated feedback voltage FB is output to the DC-DC converter 510.

The on-off predicting unit 522 receives the PWM control signal PS from the PWM control unit 540 and generates an on-off predicting signal OS in response thereto. In addition, the generated on-off expected signal OS is output to the feedback voltage controller 521. Here, as described above, the PWM control signal PS is output to the on-off expected portion 522 before the FET 550, for example.

Here, the on-off expected signal OS is a signal for predicting the on / off of the LED lamp in advance.

The on-off expected signal OS is generated in response to the PWM control signal PS input to the on-off predicted portion 522. When the PWM control signal PS input to the on-off predictor 522 is on, the on-off predictor 522 outputs a corresponding on-off predicted signal OS to the feedback voltage controller 521. On the other hand, when the PWM control signal PS input to the on-off predictor 522 is off, for example, the on-off predicted signal OS may correspond to the on-off predicted signal OS corresponding to the feedback voltage controller. 521).

The on-off predicting unit 522 receives the PWM control signal PS before the FET 550, so that the on-off of the LED lamp can be predicted in advance.

The feedback voltage controller 521 receives the max voltage MVf from the max voltage detector 530 and the on-off expected signal OS from the on-off predictor 522, and generates a feedback voltage FB in response thereto. do. In addition, the generated feedback voltage FB is output to the DC-DC converter 510.

Referring to FIG. 6, a feedback voltage controller 521 according to an embodiment of the present invention will be described in more detail.

As shown, before the operation of the LED lamp, the feedback voltage FB is gradually changed first before a predetermined time. The feedback voltage FB is changed according to the on-off expected signal OS, and the on-off expected signal OS is on-off expected portion 522 before the PWM control signal PS output to the FET 550. Is generated in response to the PWM control signal PS output to

First, the case where the LED lamp is turned on will be described in detail with an example.

Before the LED lamp is turned on, the feedback voltage FB gradually decreases in advance. Here, the feedback voltage FB is applied to the on-off expected signal OS generated in response to the PWM control signal PS applied to the on-off predictor 522 first, for example. It is controlled.

Accordingly, the output voltage Vout generated by the DC-DC converter 510 gradually increases slightly in response to the feedback voltage FB. The output voltage Vout output from the DC-DC converter 510 gradually increases slightly before the LED lamp is turned on, so that when the LED lamp is turned on, the output current Iout, that is, the LED lamp current ILED is suddenly increased. It is possible to prevent the inrush of the input current Iin and the drop of the output voltage Vout. This is because the input current Iin is gradually changed in response to the feedback voltage FB which is gradually changed in advance before the LED lamp is driven.

When the LED lamp is turned on, the feedback voltage FB increases in response to the max voltage MVf input from the max voltage detector 530, and then gradually decreases. Accordingly, it is possible to respond to a sudden change in the output current Iout of the LED lamp. Therefore, since the input current Iin is also gradually increased in advance, an inrush phenomenon of the input current Iin can be prevented. In addition, the output voltage Vout output from the DC-DC converter 510 also gradually decreases, thereby preventing a voltage drop phenomenon. As a result, an output voltage Vout capable of stably driving the LED lamp may be generated.

Hereinafter, the case where an LED lamp is turned off is explained in full detail, for example.

Before the LED lamp is turned off, the feedback voltage FB gradually increases slightly. Here, the feedback voltage FB is controlled by, for example, the on-off expected signal OS generated in response to the PWM control signal PS applied to the on-off predictor 522 first for a predetermined time off. It is.

Accordingly, the output voltage Vout generated by the DC-DC converter 510 gradually decreases slightly in response to the feedback voltage FB. The output voltage Vout output from the DC-DC converter 510 gradually decreases in advance before the LED lamp is turned off, so that when the LED lamp is turned off, the output current Iout, i.e., the sudden fall of the LED lamp current ILED, is caused. The rapid rise of the input current Iin and the output voltage Vout can be prevented. This is because the input current Iin is gradually changed in response to the feedback voltage FB which is gradually changed in advance before the LED lamp is driven.

When the LED lamp is turned off, the feedback voltage FB is gradually decreased in response to the max voltage MVf input from the max voltage detector 530. Accordingly, it is possible to respond to a sudden change in the output current Iout of the LED lamp. Therefore, since the input current Iin is also gradually decreased in advance, a sudden drop of the input current Iin can be prevented. In addition, the output voltage Vout output from the DC-DC converter 510 also gradually increases, thereby preventing a phenomenon in which the voltage increases. As a result, an output voltage Vout capable of stably driving the LED lamp may be generated.

In the embodiment of the present invention, as described above, the output voltage Vout of the DC-DC converter 510 is slightly increased in advance before the ON operation of the LED lamp, so that the output voltage Vout of the LED lamp is turned on. Corresponds to the drop phenomenon. In addition, before the LED lamp is turned off, the output voltage Vout of the DC-DC converter 510 is slightly lowered in advance to suppress the increase in the output voltage Vout after the LED lamp is turned off. That is, the DC-DC converter 510 is controlled in advance before the on-off operation of the LED lamp to maintain a stable output voltage (Vout) state.

To this end, in the embodiment of the present invention, the on-off prediction unit 520 for predicting the on-off of the LED lamp in advance is included. As described above, the on-off prediction unit 520 receives the PWM control signal PS in advance and outputs the DC-DC converter 510 before the PWM control signal PS is output to the FET 550. The voltage Vout can be controlled in advance.

Embodiment of the present invention described above is an example of the present invention, it is possible to change freely within the scope included in the spirit of the present invention. Accordingly, the invention includes modifications of the invention within the scope of the appended claims and their equivalents.

510: DC-DC converter 520: feedback voltage generator
530: Max voltage detection unit 540: PWM control unit 550: FET
521: feedback voltage control unit 522: on-off prediction unit
410: LED lamp array
MVf: Max voltage Vf: Forward voltage

Claims (6)

A liquid crystal panel;
A backlight including a plurality of LED lamp arrays comprising a plurality of LED lamps providing light to the liquid crystal panel;
It includes a lamp driver for applying an output voltage to the backlight,
The lamp driver includes a DC-DC converter, a feedback voltage generator, and a PWM controller,
The feedback voltage generator generates a feedback voltage by predicting the on / off of the LED lamp in advance according to the PWM control signal input from the PWM controller.
The DC-DC converter generates an output voltage corresponding to the feedback voltage.
LCD display device.
The method of claim 1,
The feedback voltage generation unit,
The on-off prediction unit receives the PWM control signal from the PWM control unit a predetermined time before the FET, and generates an on-off prediction signal in response thereto.
LCD display device.
The method of claim 1,
It further comprises a max voltage detection unit for detecting the max voltage of the forward voltage of the plurality of LED lamp array,
The feedback voltage generator includes a feedback voltage controller configured to receive the max voltage and generate the feedback voltage corresponding thereto.
LCD display device.
Lamp including a plurality of LED lamp array consisting of a plurality of LED lamps for providing light to the liquid crystal panel, a DC-DC converter, a feedback voltage generator, a PWM control unit for applying an output voltage to the backlight In a driving method of a liquid crystal display device comprising a driving unit,
In the feedback voltage generation unit,
Generating a feedback voltage by predicting the on / off of the LED lamp in advance according to the PWM control signal inputted from the PWM control unit;
Generating the output voltage corresponding to the feedback voltage in the DC-DC converter
Liquid crystal display device driving method comprising a.
The method of claim 4, wherein
In the feedback voltage generation unit,
And receiving the PWM control signal from the PWM control unit a predetermined time before the FET, and generating an on-off expected signal in response thereto.
Liquid crystal display driving method.
The method of claim 4, wherein
Detecting a max voltage among forward voltages of the plurality of LED lamp arrays;
In the feedback voltage generation unit,
Generating the feedback voltage corresponding to the max voltage;
Liquid crystal display driving method.

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