JP3394885B2 - Liquid crystal display - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device having gamma correction means for correcting the voltage / light transmittance characteristics of a liquid crystal display device. 2. Description of the Related Art A conventional liquid crystal display device of this type is provided with a gamma correction circuit for correcting the non-linearity of the voltage / light transmittance characteristics of the liquid crystal display element, and displays gradation with good linearity. Is going. However, since the liquid crystal display element has a strong viewing angle characteristic, it is known that the contrast is reduced and the black-and-white inversion phenomenon occurs depending on the viewing direction. That is, the liquid crystal display element has a problem that the viewing angle is narrower than that of a cathode ray tube or the like due to optical characteristics, and a displayed image is difficult to see at a position shifted from the front of the liquid crystal display element. In order to solve this problem, there is a driving method of a liquid crystal display device proposed in, for example, Japanese Patent Application Laid-Open No. 5-68221. In this method, the structure of the liquid crystal display element is the same as that of the related art, and the expression of the intermediate gradation in which the black-and-white inversion phenomenon easily occurs is performed by adding the white level and the black level at the same timing. A wide viewing angle characteristic is obtained by setting a high value and writing data to the liquid crystal display element a plurality of times in one field. As another solution, Japanese Patent Laid-Open No.
Japanese Patent No. 60225 discloses switching of a plurality of amplifiers or switching of the dynamic range of a single amplifier in accordance with the viewing angle characteristics of voltage and light transmittance, with the structure and driving frequency of a liquid crystal display element being the same as in the prior art. By doing so, a liquid crystal display device that achieves a wide viewing angle characteristic while preventing the black-and-white inversion phenomenon has been proposed. [0005] However, in the case of Japanese Patent Application Laid-Open No. 5-68221 described above, the driving frequency is increased and data is written to the liquid crystal display element a plurality of times in one field. Therefore, there is a problem that not only the circuit configuration becomes complicated, but also unnecessary radiation increases. Further, in the case of the above-mentioned Japanese Patent Application Laid-Open No. 7-160225, there is a problem that the contrast is reduced because only the dynamic range of the amplifier is switched. The present invention has been made in view of the above-mentioned points, and has a simple configuration, and can reduce the contrast, collapse, and cause the black-and-white inversion phenomenon even at a position shifted from the front of the liquid crystal display element. An object of the present invention is to provide a liquid crystal display device capable of performing gradation display with good linearity on a display image having no display. [0008] The liquid crystal display device according to the present gun onset bright SUMMARY OF THE INVENTION stores gamma correction means for correcting the voltage-light transmittance characteristic of the liquid crystal display device, in advance a plurality of the gamma correction data Data storage means, a viewing angle detection means for detecting a viewing angle with respect to the liquid crystal display element, and a data selection output means for selectively outputting gamma correction data stored in the data storage means based on the detection result. In the liquid crystal display device for performing gamma correction based on the selected gamma correction data, the gamma correction data data storage means includes a panel mark of an area where the input signal is inverted between black and white.
In order not to output the applied voltage, light
When the transmittance curve monotonically increases,
A first output point which is a boundary, and the
A second output point at which the light transmittance curve peaks
And the light transmittance curve monotonically decreases from the peak and monotonically decreases.
And a third output point at which the light transmittance curve changes from
From the third output point, the boundary of the area where monotone increases and black-and-white inversion occurs
Output point for the input signal based on the fourth output point,
When the power point is the first output point, the third output point
Or the output point for the input signal is
A gun that shifts to the fourth output point when it is the output point
The correction data is stored . [0009] Thus, appropriate gamma correction data is selectively output in accordance with the viewing direction of the liquid crystal display element, and the input signal is subjected to gamma correction based on the gamma correction data, thereby obtaining the optical characteristics of the liquid crystal display element. Is corrected, and even at a position shifted from the front of the liquid crystal display element, a gradation display with good linearity can be performed on a display image free from a decrease in contrast, a collapse, and a black-and-white inversion phenomenon. In addition, the gamma correction data is transferred to a liquid crystal display element.
Polarity inversion region of the voltage-light transmittance characteristic curve
Characteristic data that eliminates
Degradation of contrast due to viewing angle, collapse, black / white inversion
It is possible to perform gradation display with good linearity without elephant.
You. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First Embodiment of a Liquid Crystal Display Device of the Present Invention
The embodiment will be described below with reference to FIGS. This
Here, FIG. 1 shows a schematic configuration of the liquid crystal display device of the present embodiment.
FIG. 2 is a block diagram of the liquid crystal display device according to the present embodiment.
Showing changes in voltage and light transmittance characteristics depending on the viewing angle
FIG. 3 and FIG. 3 show the voltage and light of the liquid crystal display element in the present embodiment.
Table change for gamma correction of transmittance characteristics
FIG. 4 is an explanatory diagram showing a switching characteristic. In FIG . 1, 1 is an R signal input section, and 2 is an R signal input section.
A / D converter 3, gamma correction table in signal conversion circuit
4, an amplification and AC drive circuit 5, and a D / A conversion unit 6.
Has been established. 7 is a liquid crystal display element, 8 is a gamma correction table.
The bull storage unit 9 controls selection of a gamma correction table.
CPU and 10 are viewing direction detecting units. 11 is G
Signal input unit, 12 is a G signal conversion circuit, 21 is a B signal input
And 22, a B signal conversion circuit, each of which has a R
Since it is the same as that of the signal processing system, the following description will focus on the R signal processing.
Science only. In the above configuration, the viewing direction detecting unit 1
0 means a plurality of stages where the operator performs manual operation
Floor switch, stepless volume, etc. can be used
The angle sensor but to detect the installation angle of the liquid crystal display device
Or a sensor that detects the gaze of the operator.
Can be. The liquid crystal display device configured as described above
When the liquid crystal display element 7 is viewed from the front, the R signal
The signal is input from the R signal input unit 1 and is decoded by the A / D conversion unit 3.
Digital signal. Here, the CPU 9 is in the viewing direction.
In response to the fact that there is a front view from the detection unit 10,
The voltage of the liquid crystal display element 7 from the gamma correction table storage unit 8
Gamma correction of the nonlinearity correction table of light transmittance characteristics
Send it to Table 4. The digitally converted R signal is subjected to gamma correction.
Gamma-corrected in Table 4 for amplification and AC drive
The level was converted to a level suitable for the liquid crystal display element 7 by the circuit 5.
After that, it is converted to an analog signal by the D / A converter 6 and
The indicating element 7 is driven. Next, from this state, the field of view of the liquid crystal display element 7
The case where the direction is changed will be described. Of the liquid crystal display element 7
FIG. 2 shows the change in the voltage / light transmittance characteristics depending on the viewing angle.
And a ₁ is the characteristic when the liquid crystal display element 7 is viewed from the front.
Where b ₁ is the viewing direction at an arbitrary angle from the front
It shows the characteristics when changed. [0017] From FIG. 2, pairs of light transmittance in the same range T _in
Each applied voltage to the liquid crystal display element 7 for
the V ₂ for V _1, b ₁ for a _1. Also, b
The range of T _rev in _one characteristic is the slope of the voltage / light transmittance characteristic
Is the area where the polarity of the
An elephant arises. A ₁ and D ₁ represent the applied voltage of the inversion region, and B ₁ and
C ₁ represents an inflection point of the characteristic curve. [0018] That is, in the viewing angle characteristics of the b _1, view of a ₁ properties
While field angle and the applied voltage to the liquid crystal display element 7 similar v ₁
Causes the contrast to drop and the black-and-white inversion phenomenon to occur.
The Rukoto. FIG . 3 shows the voltage and light transmission of the liquid crystal display element 7 of FIG.
Conversion of tables for gamma correction for excess rate characteristics
FIG. 6 is a diagram showing characteristics, showing input and output of a gamma correction table 4;
Are represented by a horizontal axis and a vertical axis, respectively. In FIG . 3, a ₂ corresponds to a ₁ in FIG.
Gamma correction characteristics when the liquid crystal display element 7 is viewed from the front.
B ₂ corresponds to b ₁ in FIG.
Gamma correction when the viewing direction is changed to an arbitrary angle
Positive characteristics. A ₂ (fourth output point), B ₂ (third output)
Point), C ₂ (second output point), D ₂ (first output point)
Output points corresponding to A ₁ , B ₁ , C ₁ , D ₁ in FIG. 2, respectively
It is. V ₃ and V ₄ each receive a standard video signal.
This is an output range at a viewing angle of a ₂ or b ₂ when a force is applied. [0021] The dotted line of X ₁ ~X ₂ in b ₂ black-and-white inverted territory
A frequency, V when X ₁ input on example b ₂ of the characteristic curve
It shifted _rev1 minutes, gamma correction tape as moves from D ₂ to B ₂
By changing the characteristics of the cable,
I and V ₄ from the voltage V ₃ applied to the liquid crystal display element 7 I
The change in the voltage / light transmittance characteristics of the liquid crystal display element 7.
Output. Also, between X _{1 and} X ₂ , the input and
The relationship with the output is one-to-one, and there is no polarity
No black and white reversal phenomenon occurs. In the case of X ₂ input, the signal is shifted by V _rev2 ,
Set the gamma correction table as shifts from C ₂ to A ₂
The same effect can be expected. As described above, the gamma correction table for each viewing angle is provided.
Table is created in advance and stored in the gamma correction table storage unit 8.
In accordance with the detection result of the viewing direction detection unit 10,
The gamma correction table corresponding to the gamma correction table
To the input video signal.
By performing gamma correction on the liquid crystal display element 7,
Low contrast even at a position shifted from the front of the
Bottom, crush, black-and-white reversal phenomenon
Good gradation display can be realized. Next, a second embodiment of the liquid crystal display device of the present invention will be described.
For state will be described hereinafter in conjunction with FIGS. 4 and 5, the upper
The same parts as those in the first embodiment are denoted by the same reference numerals,
Description is omitted. Here, FIG. 4 shows the liquid crystal display device of the present embodiment.
FIG. 5 is a block diagram showing a schematic configuration of the device, and FIG.
Gamma compensation for the voltage and light transmittance characteristics of the liquid crystal display device
FIG. 8 is an explanatory diagram showing conversion characteristics of a table for performing correction;
You. The liquid crystal display of the present embodiment is shown in FIG.
As shown, the digitally converted R signal has a gamma correction table.
Level 4 and the level shifter 11 as well.
Is forced. This level shift unit 11 is provided by the CPU 10
Based on the value of the coordinate data (X ₁ , V _rev3 , V _rev4 )
The output of the gamma correction table 4 and V
_rev3 and _{Vrev4 are added} and subtracted, and the amplification and AC drive circuit 5
Output to It should be noted that the CPU 10 determines in advance each viewing angle.
Of the slope of the slope in the voltage-light transmittance characteristic curve
Memory (not shown) that stores the coordinate data of the transfer area
have. [0026] As described above in conjunction with FIG. 3, the X ₁ to X ₂
Since there is an inversion area between the liquid crystal display devices of the present embodiment,
As shown in FIG. 5, X _1, for example, the input from 0IRE
Until the above, the a ₂ correction characteristic is _adjusted by the level shift unit 11 for V _rev4 .
Subtracts shift, V _rev3 minutes Les from X ₁ to 100IRE
Adding shift at Berushifuto unit 11, correction JP represented by a ₃
And sex. However, the _{V rev1 <V rev3 + V rev4} . That is, as can be seen from FIG. 3, a ₂ and b ₂
Characteristics of the region other than X ₁ to X ₂ is A, song moved substantially parallel
Only X ₁ point and V _rev3 , V _rev4 because it approximates a line
Is stored in the CPU 9 or assigned to a point that is easy for the operator to see.
Be sure to translate the gamma correction table in parallel.
This can cause contrast loss, collapse, and black-and-white inversion.
Display gradations with good linearity on display images
It becomes. Therefore, in the present embodiment, as shown in FIG.
As described above, the gamma correction table in the first embodiment
Since the memory unit 8 can be omitted, the circuit configuration can be simplified.
In addition, cost can be reduced. The liquid crystal display device according to the present invention is as described above.
The viewing direction of the liquid crystal display element
Select and output appropriate gamma correction data according to
Gamma correction for input signal based on gamma correction data
By correcting the optical characteristics of the liquid crystal display element,
Even if it is shifted from the front of the liquid crystal display element,
For images that do not suffer from
Thus, gradation display with good linearity can be performed. The liquid crystal display device according to the present invention has a gun
The correction data is converted to the voltage / light transmittance characteristic curve of the liquid crystal display element.
Level shift in the polarity inversion area of the line
Characteristic data that eliminates the polarity inversion region of
Easy configuration, reduced contrast and crushing due to viewing angle
Display with good linearity without black-and-white inversion
It becomes possible.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a schematic configuration of a first embodiment of a liquid crystal display device of the present invention. FIG. 2 is an explanatory diagram showing a change in a voltage / light transmittance characteristic according to a viewing angle of a liquid crystal display element in the first embodiment of the liquid crystal display device of the present invention. FIG. 3 is an explanatory diagram showing conversion characteristics of a table for performing gamma correction on the voltage / light transmittance characteristics of the liquid crystal display element in the first embodiment of the liquid crystal display device of the present invention. FIG. 4 is a block diagram illustrating a schematic configuration of a liquid crystal display device according to a second embodiment of the present invention. FIG. 5 is an explanatory diagram showing conversion characteristics of a table for performing gamma correction on voltage / light transmittance characteristics of a liquid crystal display element in a second embodiment of the liquid crystal display device of the present invention. [Description of Signs] 1 R signal input unit 2 R signal conversion circuit 3 A / D conversion unit 4 Gamma correction table 5 Amplification and AC drive circuit 6 D / A conversion unit 7 Liquid crystal display element 8 Gamma correction table storage unit 9 CPU 10 Viewing direction detector 11 Level shifter

Claims (1)

(57) [Claim 1] Gamma correction means for correcting voltage / light transmittance characteristics of a liquid crystal display element, data storage means for storing a plurality of gamma correction data in advance, and a liquid crystal display and the viewing angle detecting means for detecting a viewing angle for the device, on the basis of the detection result, the data selection output means for the gamma correction data stored selectively outputs the data storage means by the selected gamma correction data In a liquid crystal display device that performs gamma correction, the data storage means for the gamma correction data stores a pattern of an area where black and white inversion occurs with respect to an input signal.
So that the input signal does not increase
Black and white when the light transmittance curve monotonically increases
A first output point which is a boundary of the area;
A second output at which the light transmittance curve peaks within the range.
The power point and the light transmittance curve monotonously decrease from the peak
A third output point turning from decreasing to increasing, and the light transmittance curve;
Region where the line monotonically increases from the third output point and reverses black and white
And the fourth output point which is the boundary of
The third output point is the first output point.
Shift to the power point or the output point for the input signal is
If the output point is 2, the shift to the fourth output point is performed.
A liquid crystal display device having gamma correction data stored therein.