JPH047517A - Lcd device - Google Patents

Abstract

PURPOSE:To correct variation in the brightness and contrast of a display screen by controlling the DC level and AC levels of video signals which are supplied to a liquid crystal panel in accordance with the ambient temperature. CONSTITUTION:A transistor(TR) serves to detect the temperature of the liquid crystal panel 30 and is provided nearby the liquid crystal panel 30. The resis tance value between the base and emitter of the TR varies with the temperature of the liquid crystal panel 30 and the amplitude of a rectangular wave voltage varies in accordance with the temperature of the liquid crystal panel 30. Thus, the temperature of the liquid crystal panel 30 is detected and the DC levels and AC levels (amplitude) of the video signals Vr - Vb supplied to the liquid crystal panel 30 are varied in accordance with the characteristics according to the detection output to hold the brightness and contrast in the optimum state at all times even if the temperature of the liquid crystal panel 30 varies, thereby displaying an image of superior quality.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to an LCD device.

[Summary of the invention]

The present invention corrects changes in brightness and contrast of a display screen in an LCD device by controlling the DC level and AC level of a video signal supplied to a liquid crystal panel in conjunction with the ambient temperature. This is what I did.

[Conventional technology]

Liquid crystal panels are used in direct-view television receivers, video projectors, and the like.

Document: Japanese Unexamined Patent Publication No. 1-293322 [Problem to be Solved by the Invention] However, since liquid crystal panels generally have temperature characteristics, when the ambient temperature changes, the brightness does not change or the contrast changes.

Figure 4 shows the signal voltage (applied voltage) Vs and light transmittance I.
This example shows a measurement example for a color liquid crystal panel.

As is clear from this figure, the characteristics move approximately parallel to the direction of the voltage Vs depending on the ambient temperature T, that is, the brightness of the display screen changes depending on the ambient temperature T.

This is the cause of so-called dark spots and white spots.

In particular, in a video projector using a liquid crystal panel, light that is not projected onto the screen tends to heat the liquid crystal panel, so the brightness of the display screen is even more likely to change.

Therefore, if the DC level of the video signal Vs supplied to the liquid crystal panel is changed in accordance with the temperature T so that the video signal Vs falls within the linear part of the characteristic regardless of the temperature T, the temperature T will change. Even if you do this, there should be no dark spots or white spots.

However, as is clear from Fig. 4, the characteristics do not completely shift parallel to changes in temperature T, so simply changing the DC level of video signal Vs does not provide sufficient temperature correction. .

FIG. 5 shows an example of measurement of the relationship between the ambient temperature T and the signal voltage Vs when a constant transmittance I is obtained. According to this Figure 5, since the change in the characteristics with respect to the temperature T is not linear (in Figure 4, the characteristics do not move completely parallel to the change in the temperature T), the temperature T is low. Sometimes, sufficient contrast cannot be obtained, and when the temperature T is high, the signal voltage Vs exceeds the linear range of the liquid crystal panel, so that the gradations near white and near black tend to be distorted.

Further, FIGS. 6 and 7 show the transmittance I using the viewing angle θ as a parameter. In other words, these figures show the liquid crystal panel (screen) viewed from above and from below, with the center front of the liquid crystal panel set at θ-0°. According to θ-0°, if the brightness and contrast of the display screen are optimally adjusted, when viewed from above, the screen will have reversed black and white, and when viewed from below, the amplitude of black and white will be reversed. This results in a black screen with a lack of color.

This invention attempts to solve these problems.

[Means to solve the problem]

Now, in the characteristics shown in FIG. 4, for example, find the signal voltage Vsb at the black level and the signal voltage Vsw at the white level so that the contrast is constant, and calculate the amplitude (Vsb - Vsi
When ll) is graphed, the characteristics are as shown in FIG. In the case of this characteristic, it can be approximated by a straight line, and its temperature coefficient is approximately 11 mV/'C.

Therefore, if the DC level of the video signal Vs supplied to the liquid crystal panel is corrected using this temperature coefficient, the image quality with respect to temperature changes can be improved.

Furthermore, regarding the characteristics shown in FIGS. 6 and 7, the optimal relationship between the amplitude (V sb -V sw') and the viewing angle θ is determined as shown in FIG. 9. In the case of this characteristic, the optimum amplitude (Vsb-Vsw) increases as the viewing angle θ changes from the top of the liquid crystal panel to the front to the bottom.

In addition, FIG. 10 shows the minimum value Vib of the voltage Vs that produces black color and the amplitude of the signal voltage Vs, using the viewing angle θ as a parameter.
This shows the relationship with sw, and the viewing angle θ is upward → 0 →
The amplitude Vsw increases as it goes downward.

Then, this amplitude Vsw is the optimum amplitude (Vsb-Vsw
) has the same meaning.

Therefore, as the viewing angle θ changes, the video signal Vs
If you adjust the AC level of
By adjusting the , you can create a screen without inverted black and white or floating black.

Further, in order to optimize the drive conditions of the liquid crystal panel, the gamma value γ for the viewing angle θ is determined from FIGS. 6 and 7, and the result is as shown in FIG. 11. Note that (this gamma value γ
The method for determining is as shown in Figure 13.

Further, FIG. 12 shows the temperature characteristics of the gamma value γ obtained from FIG. 4.

Therefore, if the gamma value T is controlled in accordance with the viewing angle θ, the image quality can be further improved.

This invention takes the above points into consideration, and detects the ambient temperature of the liquid crystal panel, and controls the level of the video signal supplied to the liquid crystal panel based on this detection output and adjustment by the user. It is.

[Effect]

When the ambient temperature of the liquid crystal panel changes or due to user adjustments, the level of the video signal supplied to the liquid crystal panel is corrected to compensate for the image quality.

[Embodiment] In FIG. 1, a color composite video signal is supplied from a terminal (1) to a sync separation circuit (2), a horizontal sync pulse is extracted, and this sync pulse is supplied to a clock forming circuit (3). Various clock pulses synchronized with the horizontal synchronizing pulse are formed, and these clock pulses are supplied to the respective circuits.

Also, the color composite signal from terminal (1) is
/C separation circuit (11), where the luminance signal and carrier color signal are separated and taken out, and the luminance signal is sent to the matrix circuit (14) through the contrast adjustment circuit (12) and clamp circuit (13). Supplied.

Further, the carrier color signal from the separation circuit (11) is supplied to a color demodulation circuit (15) to demodulate red and blue color difference signals, and these color difference signals are supplied to the matrix circuit (14).

In this way, from the matrix circuit (14), red, green,
Three blue primary color signals Vr, Vg, and vb are extracted.

These signals Vr to vb are then applied to the gamma correction circuit (16
) and the polarity inversion circuit (
18), and as shown in FIG. 3A, signals Vr to vb whose polarity is inverted centering on, for example, a 50% gray level 8.5cm every horizontal period, and these signals Vr -Vb is supplied to the color liquid crystal panel (30) through the drive circuit (21).

In this example, the liquid crystal panel (30) has an active matrix structure as shown in FIG. 2, where Ed is a pixel electrode, Ec is a common electrode, and Q is a switching TFT. , , GBLN is a gate pass line, and 5BLN is a source pass line.

Then, a pulse that turns on TPT (Q) is supplied from the drive circuit (22) to the gate pass line GBLN in order according to the vertical scanning position, and video signals Vr to vb are supplied from the drive circuit (21) to the source pass line GBLN. 5BLN in order according to the horizontal scanning position.

Furthermore, as will be described in detail later, as shown by the solid line in FIG. A rectangular wave voltage Vc that changes at an equal level in the vertical direction with (2) as a DC level is supplied to the common electrode Ec.

Therefore, the amplitude of the signals Vr to vb is set to Vbw (=Vsb
-Vsw), the voltage IVbw-Vcl is supplied to each pixel of the liquid crystal panel (30), so the transmittance (■) of the liquid crystal panel (30) is determined by the voltage IVbw-Vcl for each pixel.
It changes in accordance with iy-Vcl, and an image based on the video signal of the terminal (1) is displayed on the liquid crystal panel (30).

In order to improve the display image of the liquid crystal panel (30) with respect to changes in temperature T and viewing angle θ, the following configuration is further provided.

That is, a thermistor (41) is installed on the liquid crystal panel (30).
are provided adjacent to each other, and this thermistor (41
) with a variable resistor (42) connected in series to the liquid crystal panel (
41) DC voltage V whose level changes in response to temperature T
a is taken out, and this voltage Va is applied to the level correction circuit (17
) as the control voltage, and the amplitudes (Vsb-Vsw) (-Vbw) of the signals ``r'' to ``b'' are corrected as explained in FIGS. 4 and 5.

Furthermore, the voltage Va is also supplied to the gamma correction circuit (16) as its control signal.

Further, a variable resistor (43) is connected to the clamp circuit (13), and a DC voltage obtained from the variable resistor (43) is supplied to the clamp circuit (13) as its control signal. The clamp level of the luminance signal, ie, the minimum focal voltage Vib, is manually controlled.

Furthermore, a variable resistor (4) interlocked with the variable resistor (43)
4), the DC voltage obtained from this variable resistor (44) is supplied to the adjustment circuit (12) as its control signal, and the amplitude (AC level) of the brightness signal passing through this adjustment circuit (12) is ) is manually controlled in conjunction with the minimum focal voltage Vib, which is the clamp level of the clamp circuit (13).

In addition, as shown in FIG. 2, a resistor (51), a variable resistor (52), and a diode-connected transistor (
61) are connected in series, a rectangular wave voltage vh that is inverted every horizontal period is supplied to this series circuit, and a resistor (5
1) and the variable resistor (52), a rectangular wave voltage Vt that is inverted every horizontal period is taken out.

In this case, the transistor (61) is connected to the liquid crystal panel (30
), and for this purpose, the transistor (61) is provided close to the liquid crystal panel (30). Therefore, the resistance value between the base and emitter of the transistor (61) changes in accordance with the temperature T of the liquid crystal panel (30), and the amplitude of the rectangular wave voltage Vt changes depending on the temperature T of the liquid crystal panel (30). This means that it is changing accordingly. In addition, at this time, the variable resistor (52
), the rate at which the amplitude of voltage Vt changes with respect to temperature T can be changed.

This voltage Vt is then applied to transistors (62) to (6).
4), a DC voltage is also taken out from the resistor (53), the variable resistor (54), and the resistor (55), and this DC voltage and the transistor (63
) and (64) are added to form the rectangular wave voltage Vc shown in FIG. 3B, and the voltage Vc is supplied to the common electrode Ec of the liquid crystal panel (30) as described above.

According to such a configuration, the amplitude of the AC voltage Vt of the voltage Vc supplied to the common electrode Ec of the liquid crystal panel (1) is shown as a solid line, a broken line, a chain line, etc. in FIG. 3B corresponding to the temperature T. It changes like this.

Therefore, in the liquid crystal panel (30), the DC component of the signal voltage lVbw-Vc1 actually applied to the liquid crystal is
The relative positions of the video signals Vr to Vb change in response to the temperature T and are suppressed within the linear range of the characteristics shown in FIG. 4, so the temperature T of the liquid crystal panel (30) changes However, the brightness does not change, there is no blackout or whiteout, and the reproducibility of midtones is also improved.

Furthermore, when the temperature T changes, the voltage Va from the thermistor (41) changes, which causes the level correction circuit (17) to change.
Since the amplitude of the color signal VrxVb passing through is controlled in accordance with the change in temperature T, the contrast of the image displayed on the liquid crystal panel (30) is maintained constant even if the temperature T changes; Images with high contrast can be displayed without crushed blacks, crushed whites, or raised blacks or whites.

Further, when the temperature T changes, the gamma value γ is changed by the voltage Va, so that a screen without black and white inversion or black floating can be obtained.

Furthermore, when the variable resistor (43) is adjusted, the minimum pyrovoltage Vib of the signals Vr to vb changes, and
By changing the variable resistor (44) in conjunction with the variable resistor (43), the amplitude of the signal Vr-Vb (Vsb-Vs
Therefore, when the viewing angle θ changes, the variable resistor (43) can be adjusted to adjust the minimum pyrovoltage Vib.
The amplitudes of Vr and Vb (VsbVsw) are changed to display an image of appropriate quality.

Thus, according to the present invention, the temperature T of the liquid crystal panel (30) is detected, and based on the detection output, the temperature T of the liquid crystal panel (30) is detected.
Since the DC level and AC level (amplitude) of the video signal Vr-Vb supplied to 0) are changed in accordance with the characteristics shown in FIGS. 4 and 5, the temperature T of the liquid crystal panel (30)
Even if the brightness and contrast change, the brightness and contrast can always be maintained at an optimal level, allowing images to be displayed with excellent image quality.

Furthermore, by adjusting the -1 variable resistor (43),
Minimum focal voltage Vib and amplitude (V
sb-Vsw), it is possible to display an image with optimal image quality even if the viewing angle θ changes.

Note that in the above, instead of controlling the AC amplitude of the rectangular wave voltage Vc supplied to the electrode Ec, the drive circuit (2
Video signal V supplied from 1) to the liquid crystal panel (30)
The DC level of r-Vb may be directly controlled.

〔Effect of the invention〕

According to this invention, the temperature T of the liquid crystal panel (30) is detected, and the DC level and AC level (amplitude) of the video signals Vr to vb supplied to the liquid crystal panel (30) are adjusted based on the detected output. Since the changes have been made in accordance with the characteristics shown in Figures 4 and 5, even if the temperature T of the liquid crystal panel (30) changes, the brightness and contrast can always be maintained at the optimum state, resulting in excellent image quality. Images can be displayed.

Furthermore, by adjusting the variable resistor (43), the minimum focal voltage Vib and amplitude (Vs
b-Vsw), it is possible to display an image with optimal image quality even if the viewing angle θ changes.

It is.

(11) is a Y/C separation circuit, (12) is a contrast adjustment circuit, (13) is a clamp circuit, (14) is a matrix circuit, (15) is a color demodulation circuit, (16) is a gamma correction circuit, (17) ) is a level correction circuit, (18) is a polarity inversion circuit, (21), (22) is a drive circuit, (30)
is a liquid crystal panel, (41) is a thermistor, GBLN is a gate pass line, 5BLN is a source pass line, Ec is a common electrode, Ed is a pixel electrode, and Q is TPT.

Claims (1)

[Scope of Claims] An LCD device using an active matrix liquid crystal panel having a pixel electrode and a common electrode, comprising a detection element for detecting the temperature of the liquid crystal panel, and a detection output of the detection element: An LCD device, wherein the DC level and AC level of a display signal supplied to the liquid crystal panel are controlled so that the display signal falls within a linear range of applied voltage versus light transmittance characteristics of the liquid crystal panel.