JP2003084731A - Method of driving liquid crystal panel, driver for liquid crystal panel, program, and medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the occurrence of a horizontal crosstalk or the like in a liquid crystal display module. SOLUTION: This method of driving a liquid crystal panel is provided with (a) selective elements to be impressed with selective voltages or (2) non-selective elements to be impressed with non-selective voltages as a liquid crystal display element for writing of the display signals from display signal lines based on the signal levels of the scanning signals inputted from scanning signal lines in correspondence to the intersected sections of the display signal lines and scanning signal lines arranged in a matrix form, and provided with a step for inputting the scanning signals and a step for inputting the display signals, and the signal levels of the scanning signals inputted from the scanning signal lines are corrected in accordance with the number of the selecting elements to be subjected to writing of the display signals from the display signal lines based on such signal levels.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal panel driving method, a liquid crystal panel driving device, a program, and a medium.

[0002]

2. Description of the Related Art A liquid crystal module having a display side drive circuit and a scan side drive circuit for outputting drive signals to display electrodes and scan electrodes of a liquid crystal panel in which liquid crystal display elements are arranged in a matrix is provided in each scan signal line. Sequential scanning voltage is applied, and liquid crystal driving is performed by applying the selection voltage / non-selection voltage from the display signal line according to the selection / non-selection of the liquid crystal display element on the selected scanning signal line during the period of selecting each scanning signal line. The so-called time-division driving is performed.

Therefore, FIG. 2 and FIGS. 3A to 3D are used.
Such a conventional liquid crystal driving method will be described with reference to FIG.

FIGS. 3A to 3D show drive applied voltage waveforms according to this method for displaying the image pattern shown in FIG. 2, which is an explanatory view of the image pattern. In addition,
2, X1, X2, ..., X7, X8 are display signal lines, Y1, Y2, ..., Y15 are scanning signal lines, white circles are selection elements, and black circles are non-selection elements.

At this time, all of the data on the scanning signal line Y1 is selected data, and the data on the scanning signal line Y2 is selected, non-selected, non-selected, ..., Non-selected, non-selected data.

FIG. 3A shows a scanning signal waveform applied to the scanning signal line Y1, FIG. 3B shows a scanning signal waveform applied to the scanning signal line Y2, and FIG. 3C shows a display. FIG. 3D shows a display signal waveform applied to the signal line X1, and FIG. 3D shows a display signal waveform applied to the display signal line X2 (in each case, a signal waveform of approximately two horizontal periods is drawn. ).

T represents the time for selecting one scanning signal line,
In this case, the polarity inversion is performed every 5T. Further, V0 is a high level for selecting a scanning signal and a display signal, and V0
1 is a non-selection high level of the scanning signal, V2 is a non-selection high level of the display signal, V3 is a non-selection low level of the display signal,
V4 indicates a non-selection low level of the scanning signal, and V5 indicates a selection low level voltage value of the scanning signal and the display signal, respectively.

[0008]

However, in the above-mentioned conventional driving method which is generally practiced at present, the voltage applied to the selected scanning signal line by the liquid crystal load due to the selected / non-selected data on the scanning signal line. Distortion occurs on the scanning signal line, and a voltage waveform distortion amount may occur in the effective value of the scanning voltage due to the difference in the combination of selected / non-selected data on the scanning signal line.

The difference in the amount of voltage waveform distortion will be described more specifically.

FIG. 4A shows a voltage waveform applied to the intersection (that is, the selection element) of the scanning signal line Y1 and the display signal line X1, and FIG. 4B shows the scanning signal line Y2 and the display signal line X.
2 shows a voltage waveform applied to the intersection with 2 (that is, a non-selected element).

Note that V4-V5 (> 0) and V1-V2
(> 0) is equal, V1-V0 (<0) and V4-V3
Is equal to (<0). Further, the absolute value of V4-V5 (> 0) and the absolute value of V1-V0 (<0) are equal.

The liquid crystal display panel forms an equivalent circuit by the capacitance component of the liquid crystal display element and the resistance components of the display electrode lines and the scanning electrode lines.

Therefore, the movement of the liquid crystal display element is controlled by the effective voltage applied to the corresponding element, and the larger the voltage, the larger the movement of the liquid crystal display element. Further, the larger the movement of the liquid crystal display element, the larger the liquid crystal load capacitance.

After all, comparing the effective voltage applied to the selection element with the effective voltage applied to the non-selection element, the effective voltage applied to the selection element becomes larger (FIG. 4A).
Therefore, the liquid crystal load capacitance of the selected element is larger than that of the non-selected element. For example, the scanning signal line Y
Comparing the liquid crystal load capacitances of 1 and the scanning signal line Y2, the liquid crystal load capacitance of the scanning signal line Y1 having more selection elements is larger.

Thus, as for the distortion amount of the voltage waveform applied to the scanning signal line, for example, the scanning signal waveform applied to the scanning signal line Y1 (see FIG. 3A) is applied to the scanning signal line Y2. It tends to be larger than the applied scanning signal waveform (see FIG. 3B).

The present inventor has noticed that such a difference in the waveform distortion causes a difference in the transmittance of the liquid crystal display element and causes a horizontal crosstalk that occurs in a horizontal bar graph display or the like in the liquid crystal display module. is there.

In view of the above conventional problems, the present invention provides a liquid crystal panel driving method, a liquid crystal panel driving device, a program, and a medium capable of suppressing the occurrence of lateral crosstalk in a liquid crystal display module. That is the purpose.

[0018]

[Means for Solving the Problems] The first invention (Claim 1)
Corresponds to the intersection of the display signal line and the scanning signal line arranged in a matrix, and the display signal from the display signal line based on the signal level of the scanning signal input from the scanning signal line. Is a method for driving a liquid crystal panel provided with (1) a selection element to which a selection voltage is applied or (2) a non-selection element to which a non-selection voltage is applied as a liquid crystal display element, Inputting the scanning signal, inputting the display signal,
Correcting the signal level of the scanning signal input from the scanning signal line based on the number of selection elements in which the display signal is written from the display signal line based on the signal level. It is a driving method.

According to a second aspect of the present invention (corresponding to claim 2), the selection voltage is higher than the non-selection voltage, and the correction is performed by an absolute signal level for writing a display signal to the selection element. Driving of the liquid crystal panel of the first aspect of the present invention is performed so that the value becomes larger in the scanning signal line in which the number of selection elements in which the display signal is written based on the signal level is larger. Is the way.

According to a third aspect of the present invention (corresponding to claim 3), a scanning signal input from the scanning signal line is provided at an intersection of the display signal line and the scanning signal line arranged in a matrix. In order to write a display signal from the display signal line based on a signal level, (1) a selection element to which a selection voltage should be applied or (2) a non-selection element to which a non-selection voltage should be applied is a liquid crystal display element. A drive device for a provided liquid crystal panel, comprising: a scan signal line drive circuit for inputting the scan signal; and a display signal line drive circuit for inputting the display signal, and input from the scan signal line. The signal level of the scanning signal is corrected by the driving device of the liquid crystal panel based on the number of selection elements in which the display signal is written from the display signal line based on the signal level.

According to a fourth aspect of the present invention (corresponding to claim 4), the selection voltage is higher than the non-selection voltage, and the correction is performed by using an absolute signal level for writing a display signal to the selection element. The value of the liquid crystal panel of the third aspect of the present invention is set so that the value becomes larger in the scanning signal line in which the number of selection elements in which the display signal is written based on the signal level is larger. It is a drive device.

A fifth aspect of the present invention (corresponding to claim 5) is the step of inputting the scanning signal, the step of inputting the display signal, and the scanning of the liquid crystal panel driving method according to the first aspect of the present invention. All or part of the step of correcting the signal level of the scanning signal input from the signal line based on the number of selection elements to which the display signal is written from the display signal line based on the signal level It is a program to be executed.

According to a sixth aspect of the present invention (corresponding to claim 6), the step of inputting the scanning signal, the step of inputting the display signal, and the scanning in the method for driving a liquid crystal panel of the first aspect of the present invention. All or part of the step of correcting the signal level of the scanning signal input from the signal line based on the number of selection elements to which the display signal is written from the display signal line based on the signal level A medium carrying a program for execution,
It is a medium that can be processed by a computer.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) In the liquid crystal driving method of the present embodiment, the selection / selection on the scanning signal line is performed in the time division driving method.
This is a liquid crystal driving method in which a correction voltage is added to the selection signal level of the scanning signal by combining the non-selection data signals.

By this liquid crystal driving method, a correction voltage for canceling the waveform distortion of the voltage applied to the selected scanning signal line in the liquid crystal load of the scanning signal line due to the selected / non-selected data on the scanning signal line is applied. , The effective value of the scanning voltage to the liquid crystal display element can be made to be the same regardless of the selected / non-selected data on the scanning signal line, and as a result, the phenomenon of horizontal crosstalk that occurs in horizontal bar graph display etc. can be prevented. Is possible.

That is, in this embodiment, in order to display the same image pattern as that described above (see FIG. 2), the drive applied voltage waveforms shown in FIGS. 1 (a) and 1 (b) are used. Use (in FIG. 2, X1, X2, ...
..., X7 and X8 are display signal lines, Y1, Y2, ..., Y1
Reference numeral 5 indicates a scanning signal line, white circles indicate selected elements, and black circles indicate non-selected elements. At this time, all of the data on the scanning signal line X1 becomes selection data, and on the scanning signal line X2, selected, non-selected, non-selected, ...
..., non-selected, non-selected data).

Incidentally, FIG. 1A shows a scanning signal waveform applied to the scanning signal line Y1, and FIG. 1B shows a scanning signal line Y.
2 shows a scanning signal waveform applied to No. 2.

Further, as in the conventional case described above, T is 1
The time for selecting the scanning signal line is shown, and the polarity is inverted every 5T. Further, the selection voltage of the present invention is V0,
V5, and the non-selection voltages of the present invention are V2 and V3 (see FIGS. 2A to 2D). However, the signal levels for writing the display signal to the selection element of the present invention are V0 and V5 in the scanning signal line Y2 having few selection elements as in the conventional case, but in the scanning signal line Y1 having many selection elements. Is V0 + VH, V5-corrected by the correction voltage VH
VH (the signal levels for writing the display signal to the non-selected elements are V1 and V4 as in the conventional case).

As described above, the liquid crystal display panel forms an equivalent circuit by the capacitance component of the liquid crystal display element and the resistance components of the display electrode lines and the scanning electrode lines, and the movement of the liquid crystal display element is applied to the corresponding element. It is controlled by the effective voltage, and the larger the voltage, the larger the movement of the liquid crystal display element.

Further, since the liquid crystal load capacitance also increases as the movement of the liquid crystal display element increases, the effective voltage applied to the selection element is larger than the effective voltage applied to the non-selection element. The liquid crystal load capacity is larger in the case of.

Therefore, in the scanning signal line Y1 having a large number of selection elements, the liquid crystal load capacitance becomes larger and the voltage waveform distortion tends to become larger.

Therefore, in the present embodiment, the correction voltage VH is added to the selection signal level of the scanning signal (see FIG. 1A).
Is added to cancel the waveform distortion amount due to the difference in the liquid crystal load capacitance caused by the difference in the combination of data on the scanning signal lines. In short, although the distortion amount (loss due to) is increased by adding the correction voltage, it suffices that the added amount of the correction voltage exceeds the increment.

As a result, it is possible to suppress the occurrence of horizontal crosstalk or the like which occurs in the horizontal bar graph display or the like in the liquid crystal display module.

In short, the present invention corresponds to the intersections of the display signal lines and the scanning signal lines arranged in a matrix,
As the writing of the display signal from the display signal line based on the signal level of the scanning signal input from the scanning signal line, (1)
A method of driving a liquid crystal panel in which a selection element to which a selection voltage is applied or (2) a non-selection element to which a non-selection voltage is applied is provided as a liquid crystal display element, and a step of inputting a scanning signal, A step of inputting a display signal, and a step of correcting the signal level of the scanning signal input from the scanning signal line based on the number of selection elements in which the display signal is written from the display signal line based on the signal level (Of course, the selection voltage is higher than the non-selection voltage, and the absolute value of the signal level for writing the display signal to the selection element is adjusted to that signal level. In the scanning signal line in which the number of selection elements in which the display signal is written from the base display signal line is larger, the scanning signal line may be larger.

Writing of a display signal from the display signal line based on the signal level of the scanning signal input from the scanning signal line is performed at the intersection of the scanning signal line and the display signal line arranged in a matrix. Is a drive device for a liquid crystal panel provided with (1) a selection element to which a selection voltage is applied, or (2) a non-selection element to which a non-selection voltage is applied, as a scanning signal. A scan signal line drive circuit for inputting a display signal and a display signal line drive circuit for inputting a display signal, and the signal level of the scan signal input from the scan signal line is based on the signal level. It goes without saying that the present invention includes a liquid crystal panel drive device that is corrected based on the number of selection elements for which the display signals are written.

The invention is based on all or part of the liquid crystal panel driving device of the present invention described above (or device,
It is a program for causing a computer to execute the functions of elements, circuits, units, etc., and is a program that operates in cooperation with the computer. Of course, the computer of the present invention is not limited to pure hardware such as a CPU, but may include firmware, OS, and peripheral devices.

The present invention also provides all or some of the steps (or steps) of the above-described method for driving a liquid crystal panel of the present invention.
A program for causing a computer to execute an operation such as a process, an operation, an action, and the like, which operates in cooperation with the computer.

It should be noted that some means (or devices, elements, circuits, sections, etc.) of the present invention, and some steps (or steps, operations, actions, etc.) of the present invention are those plural means or It is meant to refer to some means or steps in a step, or to some functions or some operations in one means or step.

Further, some devices (or elements, circuits, parts, etc.) of the present invention mean some devices of the plurality of devices, or some means of one device. (Or, an element, a circuit, a part, etc.) or a part of the functions of one means.

A computer-readable recording medium in which the program of the present invention is recorded is also included in the present invention. Further, one usage form of the program of the present invention may be a mode in which the program is recorded in a computer-readable recording medium and operates in cooperation with the computer. Further, one usage form of the program of the present invention may be a mode in which the program is transmitted through a transmission medium, read by a computer, and operates in cooperation with the computer. The recording medium includes a ROM and the like, and the transmission medium includes a transmission medium such as the Internet and light, radio waves, sound waves and the like.

The configuration of the present invention may be realized by software or hardware.

Further, the invention is a medium carrying a program for causing a computer to execute all or some of the functions of all or some of the means for driving the liquid crystal panel of the present invention described above, and is read by the computer. The readable and readable program is a medium that cooperates with the computer to perform the functions.

The present invention is also a medium carrying a program for causing a computer to execute all or some of the steps of all or some of the steps of the liquid crystal panel driving method of the present invention described above. The readable and readable program is a medium for performing the operation in cooperation with the computer.

As described above, the present invention has, for example, a display side driving circuit and a scanning side driving circuit which output driving signals to the display electrodes and the scanning electrodes of the liquid crystal panel in which the liquid crystal display elements are arranged in a matrix. The liquid crystal module and the drive circuit for the liquid crystal display device including the timing circuit for controlling the operation of the liquid crystal module are sequentially applied with the scanning voltage to each scanning signal line, and the selection is performed during the period for selecting each scanning signal line. In the so-called time-division driving method, in which a selection voltage / non-selection voltage is applied from the display signal line according to selection / non-selection data of the liquid crystal display element on the scanning signal line to drive the liquid crystal, selection / non-selection on the scanning signal line is performed. This is a liquid crystal driving method in which a correction voltage is added to the selection signal level of the scanning signal by combining the selection signals.

Further, the present invention is characterized in that, for example, a correction voltage is added to the selection signal level of the scanning signal by a combination of selection / non-selection signals on the scanning signal line, and a liquid crystal controller IC and a liquid crystal controller IC. Driver IC
Is.

Therefore, according to the present invention, a scanning voltage is sequentially applied to each scanning signal line, and during the period in which each scanning signal line is selected, depending on the selection / non-selection of the liquid crystal display element on the selected scanning signal line, In the time-division driving method of a matrix liquid crystal display device in which a selection voltage / non-selection voltage is applied from a display signal line to drive a liquid crystal, the selection signal level of the scanning signal is changed by a combination of selection / non-selection signals on the scanning signal line. The addition of the correction voltage has a great effect in preventing the occurrence of a phenomenon such as horizontal crosstalk which occurs in a horizontal bar graph display which is a serious problem in the liquid crystal display module.

[0048]

As is apparent from the above description,
INDUSTRIAL APPLICABILITY The present invention has an advantage that it is possible to suppress the occurrence of lateral crosstalk in a liquid crystal display module.

[Brief description of drawings]

1A is an explanatory diagram of a scanning signal waveform applied to a scanning signal line Y1 according to the first embodiment of the present invention. FIG. 1B is a scanning signal according to the first embodiment of the present invention. Line Y2
Diagram of the scanning signal waveform applied to the

FIG. 2 is an explanatory diagram of an image pattern

FIG. 3A is an explanatory diagram of a conventional scanning signal waveform applied to a scanning signal line Y1. FIG. 3B is an explanatory diagram of a conventional scanning signal waveform applied to a scanning signal line Y2. FIG. 3 (c); Explanatory diagram of the conventional display signal waveform applied to the display signal line X1. FIG. 3 (d); Explanatory diagram of the conventional display signal waveform applied to the display signal line X2.

FIG. 4A is a scanning signal line Y1 and a display signal line X1.
4B is an explanatory diagram of a voltage waveform applied to the intersection of the scanning signal line Y2 and the display signal line X2.

[Explanation of symbols]

V0 Scan signal and display signal selection High level V1 Scan signal non-selection high level Non-selection of V2 display signal High level V3 Display signal non-selection high level V4 Scan signal non-selection low level V5 Scan signal and display signal selection low level VH Scan signal correction voltage Time to select T 1 scan signal line X1, X2, ..., X8 Display signal line Y1, Y2, ..., Y15 Scanning signal line

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) H04N 5/66 102 H04N 5/66 102B F term (reference) 2H093 NA16 NC02 NC09 NC10 NC11 NC16 NC34 ND15 5C006 AC22 AF42 AF45 AF50 BB12 BC03 FA22 FA36 5C058 AA06 BA01 BA10 5C080 AA10 BB05 DD10 EE25 FF12 JJ01 JJ04

Claims (6)

[Claims] 1. A display signal from the display signal line based on a signal level of a scanning signal input from the scanning signal line, corresponding to an intersection of the display signal line and the scanning signal line arranged in a matrix. Is a method for driving a liquid crystal panel provided with (1) a selection element to which a selection voltage is applied or (2) a non-selection element to which a non-selection voltage is applied as a liquid crystal display element, Inputting the scan signal, inputting the display signal, and writing a display signal from the display signal line based on the signal level of the scan signal input from the scan signal line. A method of driving a liquid crystal panel, the method comprising: 2. The selection voltage is higher than the non-selection voltage, and the absolute value of a signal level for performing the correction to write a display signal to the selection element is based on the signal level of the display signal line. 2. The method for driving a liquid crystal panel according to claim 1, wherein the display signal is written in from a scanning signal line in which the number of selection elements is larger, so as to be larger. 3. A display signal from the display signal line based on a signal level of a scanning signal input from the scanning signal line corresponding to an intersection of the display signal line and the scanning signal line arranged in a matrix. As a writing device of a liquid crystal panel drive device, a liquid crystal display device is provided with (1) a selection element to which a selection voltage is applied, or (2) a non-selection element to which a non-selection voltage is applied, A scan signal line drive circuit for inputting the scan signal and a display signal line drive circuit for inputting the display signal are provided, and the signal level of the scan signal input from the scan signal line is the signal level thereof. A drive device for a liquid crystal panel, which is corrected based on the number of selection elements in which display signals are written from the display signal line based on the above. 4. The selection voltage is higher than the non-selection voltage, and in the correction, the absolute value of a signal level for writing a display signal to the selection element is based on the signal level of the display signal line. 4. The liquid crystal panel drive device according to claim 3, wherein the display signal is written in a larger number in a scanning signal line in which a larger number of selection elements are written. 5. The liquid crystal panel driving method according to claim 1, wherein the step of inputting the scanning signal, the step of inputting the display signal, and the signal level of the scanning signal input from the scanning signal line are: A program for causing a computer to execute all or part of the step of correcting based on the number of selection elements in which the display signal is written from the display signal line based on the signal level. 6. The method of driving a liquid crystal panel according to claim 1, wherein the step of inputting the scanning signal, the step of inputting the display signal, and the signal level of the scanning signal input from the scanning signal line are: A medium carrying a program for causing a computer to perform all or part of the step of correcting based on the number of selection elements in which the display signal is written from the display signal line based on the signal level, A computer-processable medium.