KR100932551B1 - TiN mode liquid crystal display and its driving method - Google Patents

Abstract

The present invention relates to a liquid crystal display device, and more particularly, to a TN mode liquid crystal display device that can be operated in a television and a monitor mode, and a method of improving a viewing angle using the same.

The arithmetic average of R, G, and B gray level signals applied to each of two vertically adjacent subpixels is arithmeticly averaged to realize high performance viewing angle characteristics required when the TV mode is used. The method of converting two grayscale signals having the same average luminance through the table and applying them to the two subpixels again and suggesting a method for improving the viewing angle of the TN mode liquid crystal display through the proposal of the liquid crystal display suggesting a concrete implementation method thereof. I'm doing it.

Description

TN mode LCD and its driving method {TN mode LCD and the driving method}             

1 is a cross-sectional view showing a cross section of a general liquid crystal panel

2A and 2B are diagrams for explaining the operation principle of a display using the TN effect, respectively.

3 is a cross-sectional structure of one cell of a TN mode liquid crystal display device

4 is a diagram showing the overall configuration of a TN mode liquid crystal display device according to the present invention;

5 is a diagram showing a detailed configuration of a mode conversion circuit unit in a TN mode liquid crystal display device of the present invention;

FIG. 6 is a view illustrating a 2X2 subpixel driving pattern of a dot inversion method to explain a viewing angle improvement method of a TN mode liquid crystal panel according to the present invention.

FIG. 7 is a graph of a lookup table for an average gray level signal between two vertically adjacent subpixels of FIG.

8 is a flowchart illustrating a method of driving a TN mode liquid crystal display device according to the present invention.

<Brief description of the main parts of the drawing>

100: liquid crystal panel 200: driving circuit portion

300: LCM drive system 210: source driver

220: gate driver 230: timing controller

240: mode conversion circuit section 250: gamma reference voltage section

260: power supply 270: DC / DC converter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly, to a liquid crystal display device that can be used in a television and a monitor.

A liquid crystal display device is a display device that applies the optical anisotropy and polarization property of liquid crystals to a driving principle. Liquid crystals are oriented in the arrangement of molecules because their structures are thin and long, and the direction of molecular arrangement is artificially applied by applying an electric field to the liquid crystals. Can be controlled.

Accordingly, if the molecular arrangement direction of the liquid crystal is arbitrarily adjusted, the molecular arrangement of the liquid crystal is changed, and image information can be expressed using the principle that light is refracted in the molecular arrangement direction of the liquid crystal by optical anisotropy.

In general, the structure of a liquid crystal panel, which is a basic component of a liquid crystal display, will be described.                         

1 is a diagram illustrating a cross section of a general liquid crystal panel.

In the liquid crystal panel 100, two substrates 2 and 4 on which various kinds of elements are formed are formed to correspond to each other, and the liquid crystal layer 10 is interposed between the two substrates 2 and 4. have.

The liquid crystal panel 100 includes an upper substrate 4 having a color filter representing a color and a lower substrate 2 having a switching circuit capable of converting a molecular arrangement direction of the liquid crystal layer 10.

The upper substrate 4 is provided with a color filter layer 8 for implementing colors and a common electrode 12 covering the color filter layer 8.

The common electrode 12 serves as one electrode for applying a voltage to the liquid crystal 10, and the lower substrate 2 serves as a switching transistor and a signal from the thin film transistor S. And a pixel electrode 14 that serves as an electrode on the other side to receive the voltage and apply the voltage to the liquid crystal 10.

The portion where the pixel electrode 14 is formed is called the pixel portion P. FIG.

In addition, in order to prevent leakage of the liquid crystal 10 injected between the upper substrate 4 and the lower substrate 2, sealants may be formed at edges of the upper substrate 4 and the lower substrate 2. It is sealed with).

The electro-optic effect of liquid crystals is the change in the optical properties of a liquid crystal cell, which is the phenomenon of electrical light modulation, which is due to the change in liquid crystal molecules from one array state to another. .                         

The liquid crystal display device using the electrical / optical effect of the liquid crystal includes 1) a display by twisted nematic (TN) effect, 2) a display by guest host (GH) effect, and 3) a birefringent (electrically controlled birefringence) ECB. Display by effect, and 4) display by Ferroelectric Liquid Crystal (FLC) effect.

Recently, a liquid crystal display device using both a television and a monitor using such a liquid crystal display device has been proposed, and a liquid crystal display device using a television / monitor combined use of a TN mode will be described below.

TN mode liquid crystal display device is a display device that applies the TN effect of nematic liquid crystal which is the most widely used among the various electrical and optical properties of the liquid crystal described above, and focuses on changing molecular arrangement continuously when an electric field is applied to a mematic liquid crystal. Developed TN (Twisted Nematic) type and STN (Super Twisted Nematic) type are mainly used.

The TN effect constitutes a cell having a 90 ° angle on two transparent electrodes oriented so that the molecular length side of the liquid crystal is parallel to the electrode surface, and a nematic liquid crystal is injected thereinto from one electrode to the other. This effect is derived from the arrangement of the liquid crystal molecules twisted continuously 90 degrees toward the electrode surface in the longitudinal axis direction.

The STN effect refers to a shape in which the twisted angle is continuously 180 ° to 360 ° compared to the TN effect.

2A and 2B illustrate the operation principle of a display using the TN effect, respectively.

First, a Twist array cell is fabricated by constructing a cell such that the molecular arrangement of the nematic liquid crystal is 90 degrees between two substrates 20 and 40 oriented parallel to the electrode surface.

Since the twist pitch of the TN array cells is sufficiently large compared to the wavelength of visible light, the polarization direction of the linearly polarized light incident perpendicularly to both substrates 20 and 40 is determined by the twist of the liquid crystal molecules 10a during the passage of the cell. Since only 90 degrees rotates, the light passes through the first polarizing plate 60 to reach the second polarizing plate 80.

That is, the TN cell has a function of blocking light between parallel polarizers and passing light between orthogonal polarizers as shown in FIG. 2A.

On the other hand, when the applied voltage between the polarizers 60 and 80 is greater than or equal to the threshold voltage of the liquid crystal 10, the liquid crystal molecules 10a are constantly parallel to the full length direction from the central portion between the electrodes to the long axis of the liquid crystal molecules. It will rearrange and lose 90 degrees of beneficiation.

In this case, in contrast to the case of FIG. 2A, light is transmitted between parallel polarizers and light is blocked between orthogonal polarizers.

It is possible to express an image by using the operation principle of the TN mode liquid crystal display device which is widely used as described above (Fig. 2B).

As described above, the display using the TN effect has a simple structure and excellent optical characteristics. The display is generally classified into a normally black (NB) method and a normally white (NW) method.                         

In the normally black method, a pair of polarizing plates are arranged such that their polarization directions are parallel to each other, thereby displaying black in a state in which an on voltage is not applied to the liquid crystal layer (ie, an off state).

In the normally white method, a pair of polarizing plates are arranged such that their polarization directions are perpendicular to each other to display white in an off state. In this case, the normally white method is advantageous in terms of display contrast, color reproducibility, and visual dependence of the display.

By the way, when the TN mode liquid crystal display device is used as a monitor and a television as described above, the monitor is not significantly affected, but in the case of a television, the user may look at the lower field of view of the liquid crystal display. The probability is increased.

However, in the TN mode liquid crystal display device, since the refractive index anisotropy ?? n exists in the liquid crystal molecules and the liquid crystal molecules are inclined with respect to the upper and lower substrates, the contrast of the display image changes depending on the viewing direction and angle of the observer, and thus the visual dependence. Since this problem becomes large, various problems arise in observation from the lower viewing angle direction.

3 illustrates a cross-sectional structure of one cell of the TN mode liquid crystal display device.

This state indicates a case where the voltage of the halftone display is applied and the liquid crystal molecules 10a are slightly raised. In this case, in the TN mode liquid crystal display device, the surface of the pair of substrates 2,4 or (20,40) The linearly polarized light 35 passing through the normal direction and the linearly polarized light 36 and 37 passing with an inclination with respect to the normal direction have different angles crossing the liquid crystal molecules 10a.

By the refractive anisotropy Δn in the liquid crystal molecules 10a as described above, when the linearly polarized light 35, 36, 37 in each direction passes through the liquid crystal molecules 10a, normal light and abnormal light are generated, As a result, it is converted into elliptical polarization, which causes the occurrence of visual dependence.

In addition, the tilt angles of liquid crystal molecules 10a in the actual liquid crystal layer are close to the middle of the pair of substrates 2 and 4 and the edges of the pair of substrates 2 and 4. Since the liquid crystal molecules 10a are twisted at 90 degrees with respect to the normal direction, the linearly polarized light 35, 36, 37 passing through the liquid crystal layer has various birefringence effects depending on the direction or angle thereof. In response to this, complex visual dependences are represented.

As the above-described visual dependence, specifically, when the time is tilted from the normal direction of the display screen to the regular time direction, which is the lower side of the display surface, the display image is colored at a certain angle or the black and white is reversed. .

In addition, when the angle is tilted in the half-time direction, which is the upper direction of the display screen, the contrast sharply decreases.

In order to improve the visual dependence of the TN mode liquid crystal display such as a television and a monitor, a wide-view film has recently been used, but the improvement efficiency with respect to the lower viewing angle is very small. to be.

In order to solve the above problems, the present invention provides a liquid crystal display device and a driving method thereof, which can be converted to a combination of a television and a monitor, which is generally used in a monitor mode that does not require high viewing angle performance. In this case, a conventional liquid crystal display device driving method is used, and when driving in a television mode, an object of the present invention is to provide a liquid crystal display device capable of providing a relatively high viewing angle performance.

In order to achieve the above object, the present invention includes a liquid crystal panel having a plurality of pixel regions defined by a plurality of gate lines and data lines perpendicular to each other; A source driver for inputting a data signal to each data line of the liquid crystal panel, a gate driver for applying a gate driving signal to each gate line of the liquid crystal panel, a gate driver signal for driving the gate driver and the source driver A timing controller for outputting a first gradation signal for driving; a mode conversion circuit unit for converting into a television mode and a monitor mode by using the first gradation signal output from the timing controller and input to the source driver; A gamma reference voltage unit for supplying a reference voltage for converting digital data input to the source driver into analog data, a power supply unit for supplying voltage to the liquid crystal panel and each component, and an output from the power supply unit. Various voltages required for driving the liquid crystal panel using voltage A driving circuit unit including a DC / DC converter for converting and outputting a voltage; An LCM driving system for outputting a data signal, a synchronization signal, a data enable signal, and a clock signal to the driving circuit unit, wherein the mode conversion circuit unit comprises: a switching element for selecting a television mode and a monitor mode; A line memory unit for receiving and storing a first gray level signal of an odd-numbered row among R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel; The first gray level signal of the even-numbered row among the R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel is input, and is located in the same column as the first gray level signal of each subpixel of the odd-numbered row. An average gradation signal generation section for generating R, G, B average gradation signals obtained by arithmetically averaging the first gradation signals of even-numbered row subpixels; A lookup table storage unit which stores a plurality of lookup tables configured to generate a new grayscale signal according to the generated average grayscale signal; The present invention proposes a TN mode liquid crystal display comprising a second gray level signal output unit which outputs two R, G, B second gray level signals according to the lookup table and outputs them to the source driver.

The switching device is characterized in that the multiplexer.

delete

In addition, the line memory unit is characterized in that the RAM.

In addition, the lookup table storage unit is characterized in that the ROM.

The plurality of lookup tables may be configured to generate gray level signals in which the arithmetic mean of the second gray level signal values is the same as the average gray level signal value.

In the driving of the TN mode liquid crystal display according to the present invention having the configuration and features as described above, the method comprising: selecting a mode using the switching element; If the selected mode is a monitor mode, transmitting the first gray level signal to the source driver; When the selected mode is a television mode, the first gray level signal of the odd-numbered row of the first gray level signal is transmitted to the line memory unit, and the first gray level signal of the even-numbered row of the first gray level signal is generated. Transmitting to the negative; The average gradation signal generation unit may include a first gradation signal of one subpixel of an odd-numbered row stored in the line memory unit and a first gradation of one subpixel of an even-numbered row vertically adjacent to one subpixel of the odd-numbered row. Generating an average gray level signal by performing an arithmetic mean of the signals; TN mode including reading the lookup table and outputting two R, G, and B second gradation signals to the source driver according to setting of a lookup table according to the average gradation signal. A method of driving a liquid crystal display device is proposed.

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

4 is a diagram illustrating an overall configuration of a TN mode liquid crystal display according to an exemplary embodiment of the present invention, in which pixel regions defined by a plurality of gate lines G and data lines D perpendicular to each other cross each other in a matrix form. The liquid crystal panel 100 is arranged, and the driving circuit unit 200 and the liquid crystal module (LCM) driving system 300 for supplying various driving signals and data signals to the liquid crystal panel.

The driving circuit unit may include a source driver 210 for inputting a data signal to each data line of the liquid crystal panel, a gate driver 220 for applying a gate driving signal to each gate line of the liquid crystal panel, and the gate driver. Television mode and monitor using a timing controller 230 for outputting a gate driving signal for driving and a first gradation signal for driving the source driver, and a first gradation signal output from the timing controller and input to the source driver. A mode conversion circuit 240 for performing a conversion to a mode, a gamma reference voltage unit 250 for supplying a reference voltage necessary for converting digital data input to the source driver into analog data, and the liquid crystal A power supply unit 260 for supplying voltage to the panel and each component, and a voltage output from the power supply unit; And a DC / DC converter 270 that converts and outputs various voltages required for driving the liquid crystal panel, and includes R, G, and B data signals output from the timing controller (ie, R, G, and B). The first gray level signal is transmitted to the source driver 210 through the mode conversion circuit 240.

Here, the mode conversion circuitry 240 includes a switching element 241 for selecting a television mode and a monitor mode; A line memory unit 242 for receiving and storing a first gray level signal of an odd-numbered row among R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel; The first gray level signal of the even-numbered row among the R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel is input, and is located in the same column as the first gray level signal of each subpixel of the odd-numbered row. An average gradation signal generation unit 243 for generating R, G, B average gradation signals obtained by arithmetically averaging the first gradation signals of even-numbered row subpixels; A look-up table storage unit (244) for storing a plurality of look-up tables set to generate a new gray-scale signal according to the generated average gray-scale signal; And a second tone signal output part 245 for outputting two R, G, and B second tone signals according to the look-up table setting, and outputting the second tone signals to the source driver.

The detailed configuration of the mode conversion circuit 240 shown in FIG. 5 will be described with reference to the dot inversion 2 × 2 subpixel driving pattern of the general TN mode liquid crystal panel of FIG. 6 as shown in FIG. In the R, G, and B first gray level signals output from the timing controller 230 to drive the liquid crystal panel 100 including subpixels, a switching element 241 for selecting a television mode and a monitor mode. ) Is configured using a multiplexer (MUX).

In order to receive and store a first gray level signal for subpixels of odd-numbered rows among the R, G, and B first gray level signals input from the timing controller 230 to drive one frame of the liquid crystal panel 100. A line memory unit 242 using a read only memory (ROM) or erasable programmable ROM (EPROM) or the like is configured, and the line memory unit 242 corresponds to an odd numbered one row of grayscale signals of one frame continuously input. The gradation signal is received and stored.

The average gray level signal generator 243 may be configured to generate a first gray level signal for each sub-pixel PX2 of an even-numbered row among R, G, and B first gray level signals input to drive one frame of the liquid crystal panel 100. R, G obtained by performing an arithmetic average of the first gray level signals of the even-numbered row subpixels PX2 positioned in the same column as the first gray level signals of the odd-numbered rows stored in the line memory unit 242. , B Generate the average gradation signal.

The lookup table storage unit 244 compares the average gray level signal output through the average gray level signal generator 243 with a stored table and generates a plurality of lookup tables (LUTs) having a setting result for generating a new gray level signal. Is saving. In the present invention, two lookup tables (LUTs) are related to resetting gray level signals for two vertically adjacent subpixels.

The second gray level signal output unit 245 generates a second gray level signal according to a result of setting the lookup table (LUT) and outputs the second gray level signal to the source driver 210.

In the TN mode liquid crystal display device for a television and a monitor according to the present invention to be implemented using the above configuration, the principle of improvement of the lower viewing angle in the television mode is shown in the TN mode liquid crystal panel driving pattern of FIG. The lookup table algorithm of FIG. 7 and the flowchart of FIG. 8 will be described.

The lookup table algorithm as shown in FIG. 7 illustrates a target value for converting the input average gray level signal into two preset gray level signals, and various target values can be changed according to a user's setting.

First, the user selects the television mode or the monitor mode for use of the liquid crystal display according to the present invention as described above, and this selection is specifically realized through switching of the multiplexer 241 (S1).

When the monitor mode is used in the above-described selection, the same driving circuit connection and configuration as that of the normal TN mode liquid crystal display device transmitting the first gray level signal to the source driver 210 is made. The circuit is configured to send the first gradation signal to the memory unit 242 and the average gradation signal generation unit 243.

In the television mode, the first gray level signal of the odd-numbered row among the input first gray level signals is input to the line memory unit 242, and the first gray level signal of the even-numbered row among the first gray level signals inputted is The average gradation signal generation unit 243 is input (S2).

Next, the average gray level signal generator 243 may include a first gray level signal of each subpixel of an odd-numbered row stored in the line memory unit 242, and an even-numbered number adjacent to each subpixel of the odd-numbered row. The first gradation signal of each subpixel in the row is arithmetic averaged to be converted into an average gradation signal value.

The converted average gray level signal is input to the lookup table storage unit 244 and a second gray level signal whose average is converted into two gray level signals equal to the average gray level signal by setting definitions of the stored lookup table LUT. The second gray level signal generator 245 is generated and transmitted to the source driver 210 (S4).

The above operation flow is performed by creating a look-up table (LUT) that defines a relationship between luminance and gradation level in a pair of vertically adjacent subpixels PX1 and PX2. After calculating a target gray level signal n _t for a pair of subpixels, each of the subpixels is converted into two different gray level signals n ₁ and n ₂ using the look-up table LUT. The method of applying to (PX1) and (PX2) is taken, which will be described in more detail as follows.

For example, in the case of an 8-bit gray scale per subpixel, the gradation signal is generated at 255 levels, and the luminance Y of the subpixel according to each level at this time is calculated by the following formula (1).                     

Formula (1)

When the luminance of each of the two gray level signals n ₁ and n ₂ generated through the lookup table LUT is Y1 and Y2, the average gray level signal n _t is

Formula (2)

It is expressed as

The two digital gradation signals reconverted by the above formulas have different signal values, for example, when gamma (γ) is 2.2 and the power factor P is 2.2 (solid line shape in FIG. 7, Of course, when the gray scale level (horizontal axis) averaged to the dotted line form is the most preferable linear form (100), the gray level is approximately 140, and the bright side has a high gray level (n _b ). For example, a signal having a gradation signal level of about 60 is a dark side having a low gradation signal value n _d . Of course, the average of the two gray level signal values will be 100.

By applying the above formula and calculating the gradation signal levels (n _d , n _b ) of the two pairs of vertical pixels, it can be expressed by the following formula (3) (4).

Formula (3)

Formula (4)

In this case, as the powering index P increases, the distance between the two curves representing the two gray level signals n _d and n _b will be further increased. Accordingly, the two subpixels PX1 and PX2 will be increased due to the characteristics of the TN mode. ) Have different tilt angles, and the viewing angle characteristic in the television mode is improved.

Of course, according to the table setting value of the look-up table LUT, it is natural that the second gray level signal can be derived in the form as shown in the solid line of FIG. 7. The tilt angles for the two subpixels on the panel will be adjustable, so that the width at which the viewing angle is improved will also be adjustable.

According to the present invention as described above, in the TN mode liquid crystal display device, the average of the gray level signal applied to two vertically adjacent subpixels is obtained, and the gray level signal is reconstructed using a set lookup table for outputting a specific luminance. The method is applied to the subpixel.

This means that the two pixels have different luminance due to different gray level signals, but the average is the same as before reconstructing the gray level signal. However, in the TN mode liquid crystal display device, since the tilt angles between the two subpixels are different from each other, there is an advantage that a lower viewing angle improvement effect can be derived when used for a television.

Claims (7)

A liquid crystal panel having a plurality of pixel regions defined by a plurality of gate lines and data lines perpendicular to each other; A source driver for inputting a data signal to each data line of the liquid crystal panel, a gate driver for applying a gate driving signal to each gate line of the liquid crystal panel, a gate driver signal for driving the gate driver and the source driver A timing controller for outputting a first gradation signal for driving; a mode conversion circuit unit for converting into a television mode and a monitor mode by using the first gradation signal output from the timing controller and input to the source driver; A gamma reference voltage unit for supplying a reference voltage for converting digital data input to the source driver into analog data, a power supply unit for supplying voltage to the liquid crystal panel and each component, and an output from the power supply unit. Various voltages required for driving the liquid crystal panel using voltage A driving circuit unit including a DC / DC converter for converting and outputting a voltage; LCM driving system for outputting a data signal, a synchronization signal, a data enable signal and a clock signal to the drive circuit unit And the mode conversion circuit unit comprises: a switching element for selecting a television mode and a monitor mode; A line memory unit for receiving and storing a first gray level signal of an odd-numbered row among R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel; The first gray level signal of the even-numbered row among the R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel is input, and is located in the same column as the first gray level signal of each subpixel of the odd-numbered row. An average gradation signal generation section for generating R, G, B average gradation signals obtained by arithmetically averaging the first gradation signals of even-numbered row subpixels; A lookup table storage unit which stores a plurality of lookup tables configured to generate a new grayscale signal according to the generated average grayscale signal; A second gradation signal output unit for outputting two R, G, and B gradation signals according to the lookup table to the source driver TN mode liquid crystal display device comprising a delete The method according to claim 1, The switching device is a TN mode liquid crystal display, characterized in that the multiplexer The method according to claim 1, TN mode liquid crystal display, characterized in that the line memory unit RAM The method according to claim 1, The lookup table storage unit is a ROM, characterized in that the TN mode liquid crystal display device The method according to claim 1, The plurality of lookup tables allow the TN mode liquid crystal display to generate gray level signals in which the arithmetic mean of the second gray level signal values is the same as the average gray level signal value. A liquid crystal panel having a plurality of gate lines and data lines, a source driver for applying a gray level signal to a data line of the liquid crystal panel, a timing controller for outputting a first gray level signal to the source driver, A switching element for performing the selection of the television mode and the monitor mode so as to be able to perform the conversion to the television mode and the monitor mode by using the first gradation signal output from the timing controller and input to the source driver; A line memory unit for receiving and storing a first gray level signal of an odd-numbered row among R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel; The first gray level signal of the even-numbered row among the R, G, and B first gray level signals inputted to drive one frame of the liquid crystal panel is input, and is located in the same column as the first gray level signal of each subpixel of the odd-numbered row. An average gradation signal generation section for generating R, G, B average gradation signals obtained by arithmetically averaging the first gradation signals of even-numbered row subpixels; A lookup table storage unit which stores a plurality of lookup tables configured to generate a new grayscale signal according to the generated average grayscale signal; In driving a TN mode liquid crystal display device having a mode conversion circuit unit including a second tone signal output unit for outputting two R, G, and B second tone signals according to the setting of the lookup table and outputting the second tone signals to the source driver. , Selecting a mode using the switching device; Transmitting the first gray level signal to the source driver when the selected mode is a monitor mode; When the selected mode is a television mode, the first gray level signal of odd-numbered rows of the first gray level signal is transmitted to the line memory unit and stored, and the first gray level signal of even-numbered rows of the first gray level signals is averaged. Transmitting to a gradation signal generation unit; The average gradation signal generation section includes a first gradation signal of one subpixel of an odd-numbered row stored in the line memory unit, and a first gradation of one subpixel of an even-numbered row perpendicularly adjacent to one subpixel of the odd-numbered row. Generating an average gray level signal by performing an arithmetic mean of the signals; Reading the lookup table and outputting two R, G, and B second gradation signals to the source driver according to a setting of a lookup table according to the average gradation signal; TN mode liquid crystal display device driving method comprising a

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