JPH09113871A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To easily perform the changing over of and the adjusting of color temps. on a liquid crystal panel without making the structure of a device complex and to obtain a satisfactory display performance by performing the changing over of and the adjusting of the color temps. of a backlight electrically. SOLUTION: A signal processing means 1 generates three-primary color signals from an input video signal. A liquid crystal panel 2 performs a screen display based on the three-primary signals generated in the signal processing means 1. A specifying means 3 specifies the color temp. of the illuminating light of a backlight 7 with respect to the liquid crystal panel 2. A control means 4 generates two kinds of luminance adjusting signals (a), (b) corresponding to two kinds of emitted lights whose colors are different. The backlight 7 lights the liquid crystal panel 2 by lights obtained by synthesizing the two kinds of lights in the light emitting ratio based on luminance adjusting signals (a), (b) generated in the control means 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device for displaying a screen on a liquid crystal panel and irradiating the displayed liquid crystal panel with a backlight, and more particularly to switching a color temperature on the liquid crystal panel. The present invention relates to a necessary liquid crystal display device.

[0002]

2. Description of the Related Art Generally, a liquid crystal display device has a reflection type in which light incident from the front surface of a liquid crystal panel is reflected by a reflection plate,
There is a transmissive type that transmits light from the back surface of the liquid crystal panel.
The transmissive liquid crystal display device includes a system in which ambient light is incident and a system in which a dedicated light source, for example, a backlight for illuminating a liquid crystal panel is used. Such liquid crystal display devices have been put to practical use as display devices for wrist watches, electronic desk calculators, character / graphics displays, televisions, and the like, and have become widespread.

For example, in a liquid crystal display device using a backlight, there is a liquid crystal display device in which the color temperature on the liquid crystal panel needs to be switched or adjusted depending on the application of the liquid crystal display device. Generally, since the color temperature of the backlight cannot be electrically changed, such a liquid crystal display device is
For example, the color temperature on the liquid crystal panel is switched or adjusted (hereinafter simply referred to as color temperature switch) by adjusting the voltage applied to the liquid crystal. Also, instead of adjusting the voltage applied to the liquid crystal, a color filter is used to replace the color filter according to the color temperature switching, or the backlight lamp is replaced according to the color temperature switching to switch the color temperature. In some cases.

[0004]

However, when the applied voltage of the liquid crystal is adjusted in order to switch the color temperature, the dynamic range becomes small, and the liquid crystal characteristics cannot be exhibited 100%. Good display performance could not be obtained.

Further, when the color filter is used, the structure of the liquid crystal display device becomes complicated and it is very troublesome to replace the color filter according to the color temperature switching.

Further, when the lamp of the backlight is replaced, this is similar to the case where the color filter is used.
As the structure of the backlight becomes complicated, it is very troublesome to replace the lamp according to the color temperature switching.

Accordingly, the present invention has been made in view of the above-mentioned conventional circumstances, and has the following objects.

That is, an object of the present invention is to electrically switch or adjust the color temperature of the backlight so that the color temperature on the liquid crystal panel can be easily switched or adjusted without complicating the structure of the device. It is to provide a liquid crystal display device capable of performing the above and obtaining good display performance.

[0009]

In order to solve the above-mentioned problems, a liquid crystal display device according to the present invention includes a signal processing means for generating three primary color signals from an input video signal, and three primary color signals generated by the signal processing means. A liquid crystal panel for displaying a screen based on a signal, a backlight for illuminating the liquid crystal panel by emitting at least two kinds of light having different emission colors, and a color temperature of illumination light of the backlight for the liquid crystal panel are designated. And a control unit that controls the signal processing unit and the backlight according to the color temperature designated by the designating unit. Then, the control means generates at least two types of brightness adjustment signals corresponding to the at least two types of light emission. The backlight is characterized in that the liquid crystal panel is illuminated with light obtained by combining the at least two types of light at an emission ratio based on at least two types of brightness adjustment signals generated by the control means.

Further, the liquid crystal display device according to the present invention is characterized in that the backlight includes at least two lamps for emitting at least two kinds of light having different emission colors.

In the liquid crystal display device according to the present invention, the control means has a storage means for storing color temperature information corresponding to the color temperature designated by the designating means. And
The control means reads out the color temperature information corresponding to the color temperature designated by the designation means from the storage means, and generates the at least two types of brightness adjustment signals from the read color temperature information. .

[0012]

Embodiments of the present invention will be described below in detail with reference to the drawings.

The liquid crystal display device according to the present invention is constructed as shown in FIG.

This liquid crystal display device 100 includes a signal processing circuit 1 to which a video signal is supplied via an input terminal I ₁ and a liquid crystal panel (hereinafter referred to as LC) to which an output of the signal processing circuit 1 is supplied.
D: It is called Liquid Crystal Display panel. 2), a changeover switch 3, a microcomputer (hereinafter, referred to as a microcomputer) 4 to which an output of the changeover switch 3 and a color temperature adjustment signal input via an input terminal I ₂ are respectively supplied, The inverter 6 to which the output is supplied and the backlight 7 to which the output of the inverter 6 is supplied
And a memory 5 for reading and writing data by the microcomputer 4.

First, the microcomputer 4 generates color temperature data corresponding to a color temperature (hereinafter referred to as a set color temperature) that can be set by the changeover switch 3 described later. That is, the microcomputer 4 uses the color temperature adjustment signal input via the input terminal I ₂ to generate color temperature data adjusted for each set color temperature, and to generate the color temperature corresponding to each set color temperature. The data is stored in the memory 5.

The changeover switch 3 described above is designed to be able to set the color temperature on the liquid crystal panel 2. The color temperature information set by operating the changeover switch 3 is supplied to the microcomputer 4. To be done.

Therefore, the microcomputer 4 reads out the color temperature data corresponding to the color temperature from the memory 5 according to the color temperature information from the changeover switch 3, that is, according to the color temperature set by the changeover switch 3. . Then, the microcomputer 4 generates an RGB adjustment signal and two types of brightness adjustment signals a and b from the color temperature data read from the memory 5, and supplies the RGB adjustment signal to the signal processing circuit 1,
Two kinds of brightness adjustment signals a and b are supplied to the inverter 6.

The signal processing circuit 1 detects, for example, a horizontal synchronizing signal or a vertical synchronizing signal from a video signal input through the input terminal I ₁ (hereinafter referred to as an input video signal),
In synchronization with the detected horizontal sync signal or vertical sync signal, a timing signal required for screen display is generated, and an input video signal is converted into an RGB signal that matches the characteristics of the LCD panel 2. In addition, the signal processing circuit 1 includes an LCD panel 2
RG from the microcomputer 4 so that the color temperature of
The RGB signal is adjusted using the B adjustment signal. Then, the signal processing circuit 1 supplies the timing signals necessary for screen display and the adjusted RGB signals to the LCD panel 2, respectively.

The LCD panel 2 displays an image based on the timing signal supplied from the signal processing circuit 1 and an image based on the RGB signal supplied from the signal processing circuit 1 simultaneously with the timing signal. It is assumed that the voltage applied to the LCD panel 2 at this time is set to an optimum value.

On the other hand, the inverter 6, as shown in FIG. 2, is composed of two systems of circuits, and a brightness control signal a from the microcomputer 4 is supplied through an input terminal I _a to a dimming circuit. 61a and, dimmer circuit and the lamp lighting circuit 62a to output the 61a is supplied, luminance adjustment signal b is input dimming circuit is supplied through the I _b from the microcomputer 4 6
1b and a lamp lighting circuit 62b to which the output of the dimming circuit 61b is supplied. The output of the lamp lighting circuit 62a is supplied to the lamp 71a of the backlight 7 described later, and the output of the lamp lighting circuit 62b is The backlight 71 is supplied to a lamp 71b which will be described later.

Light control circuit 61a and lamp lighting circuit 62a
Is for lighting the lamp 71a, and the dimming circuit 61
b and the lamp lighting circuit 62b are for lighting the lamp 71b, and the brightness of the lamp 71a and the lamp 71b can be controlled by the brightness adjusting signal a and the brightness adjusting signal b from the microcomputer 4, respectively. ing.

Here, FIG. 3 shows two lamps 71a, 7a.
It is sectional drawing which looked at the structure of the backlight 7 provided with 1b from the side surface.

That is, in the backlight 7, the above-mentioned lamps 71a and 71b, the light guide plate 75 on which the light from the lamps 71a and 71b is incident, and the light incident on the light guide plate 75 are LCDs.
A light emitting surface 72 provided so as to illuminate the panel 2, a reflecting plate 74 provided so as to guide the light inside the light guide plate 75 to the light emitting surface 72, and the light from the lamps 71a, 71b enter efficiently. The reflection sheet 73 is provided.

In the backlight 7 as described above, lamps having different emission colors are used here as the lamps 71a and 71b. For example, a lamp having a low color temperature is used as the lamp 71a, and a blue lamp is used as the lamp 71b.

The light emission ratio of the lamps 71a and 71b can be changed by the outputs of the above-mentioned lighting circuit 62a and lighting circuit 62b.

More specifically, as shown in FIG.
The dimming circuit 61a uses the brightness adjustment signal a from the microcomputer 4 to generate an output signal S _a with _a constant ratio of the on period and the off period. On the other hand, the dimming circuit 61b includes the microcomputer 4
From the output signal S _a having a constant ratio of the on period and the off period by using the brightness adjustment signal b from
The output signal S _b with the changed ratio of the f period is generated.

That is, the dimming circuit 61a outputs the output signal S
_a the on period and the off period value T _aon, sets the T _aoff a constant value, the dimming circuit 61b varies the value of the on period and the off period of the output signal S _b, for example, the on period values T
_b1on , off period value T _b1off to on period value T
_b2on , off period value T _b2off , the on period value is ΔT
To set the values of the on period and the off period.

As described above, the output signal S _a generated by the dimming circuit 61a is supplied to the lamp lighting circuit 62a, and the output signal S _b generated by the dimming circuit 61b is supplied to the lamp lighting circuit 62a. Supplied. The lamp lighting circuit 62a supplies the lamp voltage to the lamp 71a based on the output signal S _a from the dimming circuit 61a, and the lamp lighting circuit 62b based on the output signal S _b from the dimming circuit 61b. , Lamp voltage is supplied to the lamp 71b. The lamp 71a is turned on by the lamp voltage from the lamp lighting circuit 62a, and the lamp 71b is turned on by the lamp lighting circuit 62b.
Lights by the lamp voltage from.

Therefore, the light emission intensity of the lamp 71a does not change and emits light at a constant intensity, and the blue lamp 71b has a Δ
The emission intensity of blue is changed and light is emitted for a time corresponding to T.

In this way, the lights from the two types of lamps 71a and 72b whose light emission ratios are changed are combined in the light guide plate 75 shown in FIG. 3 and guided to the light emitting surface 72. At this time, the color temperature of the light emitting surface 72, that is, the color temperature of the backlight 7 becomes the color temperature set by the changeover switch 3.

FIG. 5 is a diagram showing changes in the color temperature of the backlight 7. The point A shown in FIG. 5 is the dimming circuit 61.
b is FIG 4 to the value of the on period shown T _B1on, in the case of outputting the output signal S _b value T _B1off the off period backlight 7 color temperature (high color temperature), shown in FIG. 5 The point A is the value T during the on period shown in FIG.
_{It is} the color temperature (low color temperature) of the backlight 7 when the output signal S _b having the value T _{b2off in} the _b2on and off period is output. In this way, by changing the time ΔT shown in FIG. 4, the color temperature of the backlight 7 changes from the point B to the point A.

FIG. 6 is a diagram showing the spectral characteristic of the LCD panel 2 when the LCD panel 2 is illuminated by the light emitted from the backlight 7 and having a changed color temperature. Figure 6 above
As shown in FIG. 5, at the point B (high color temperature) in FIG. 5, the blue lamp 71b has a strong emission intensity like a curve A, and at the point A (low color temperature) in FIG. 7
The curve B has a weak emission intensity of 1b.

As described above, in the liquid crystal display device 100,
By using two kinds of lamps 71a, 71b having different emission colors and controlling the respective emission intensities based on the setting of the changeover switch 3, the color temperature of the LCD panel 2 is adjusted and changed electrically. You can Further, the user can freely set the color temperature of the LCD panel 2 by using the changeover switch 3. Furthermore, since it is not necessary to change the electrical condition of the applied voltage of the LCD panel 2 adjusted to the optimum value, 100% of the liquid crystal characteristics can be exhibited, so that good display performance of the LCD panel 2 can be obtained. it can. Furthermore, since it is not necessary to replace the color filter or the lamp, the structure of the backlight 7 does not become complicated.

In the liquid crystal display device 100, the color temperature of the LCD panel 2 is set by the changeover switch 3, but the volume of the color temperature adjusting signal supplied to the microcomputer 4 is changed without using the changeover switch 3. The color temperature of the LCD panel 2 may be set by directly changing the above.

[0035]

In the liquid crystal display device according to the present invention, the signal processing means generates the three primary color signals from the input video signal. The liquid crystal panel displays a screen based on the three primary color signals generated by the signal processing means. The designating unit designates the color temperature of the illumination light of the backlight with respect to the liquid crystal panel. The control means generates at least two types of brightness adjustment signals corresponding to at least two types of light emission having different emission colors. The backlight illuminates the liquid crystal panel with light obtained by combining the at least two types of light at an emission ratio based on the at least two types of brightness adjustment signals generated by the control means. Accordingly, the color temperature of the liquid crystal panel can be adjusted and switched electrically. Further, the user can freely set the color temperature of the liquid crystal panel by using the designating means. Furthermore, since it is not necessary to change the electrical condition of the applied voltage of the liquid crystal panel, by adjusting the applied voltage of the liquid crystal panel to an optimum value,
The characteristics of liquid crystal can be exhibited 100%. Therefore, good display performance of the liquid crystal panel can be obtained. Furthermore, since it is not necessary to replace the color filter or the lamp, the structure of the backlight is not complicated. Therefore, without complicating the structure of the device,
The color temperature on the liquid crystal panel can be easily switched or adjusted, and good display performance can be obtained.

Further, in the liquid crystal display device according to the present invention, the backlight emits at least two kinds of light having different emission colors by at least two lamps. Accordingly, the backlight can illuminate the liquid crystal panel with light that is a combination of at least two types of light having different emission colors.

Further, in the liquid crystal display device according to the present invention, the storage means of the control means stores color temperature information corresponding to the color temperature designated by the designation means. Then, the control means reads out color temperature information corresponding to the color temperature designated by the designation means from the storage means,
At least two types of brightness adjustment signals are generated from the read color temperature information. Thereby, the control means can control the color temperature on the liquid crystal panel to an optimum color temperature.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a liquid crystal display device according to the present invention.

FIG. 2 is a block diagram showing a configuration of an inverter.

FIG. 3 is a block diagram showing a configuration of a backlight.

FIG. 4 is a diagram for explaining an output signal of the adjustment circuit.

FIG. 5 is a diagram for explaining a color temperature of a backlight.

FIG. 6 is a diagram for explaining a spectral characteristic of an LCD panel.

[Explanation of symbols]

 1 Signal Processing Circuit 2 LCD Panel 3 Changeover Switch 4 Microcomputer 5 Memory 6 Inverter 7 Backlight 100 Liquid Crystal Display Device

Claims (3)

[Claims] 1. A signal processing means for generating three primary color signals from an input video signal, a liquid crystal panel for displaying a screen based on the three primary color signals generated by the signal processing means, and at least two different emission colors.
A backlight that emits light of various kinds to illuminate the liquid crystal panel, a designating unit that designates a color temperature of the illumination light of the backlight with respect to the liquid crystal panel, and the color temperature designated by the designating unit. Signal processing means and control means for controlling the backlight, respectively, wherein the control means generates at least two types of brightness adjustment signals corresponding to the at least two types of light emission, and the backlight is the control means. A liquid crystal display device, which illuminates the liquid crystal panel with light that combines the at least two types of light at an emission ratio based on at least two types of generated brightness adjustment signals. 2. The liquid crystal display device according to claim 1, wherein the backlight includes at least two lamps that emit at least two types of light having different emission colors. 3. The control means has storage means for storing color temperature information corresponding to the color temperature designated by the designating means, and color temperature information corresponding to the color temperature designated by the designating means. 2. The liquid crystal display device according to claim 1, wherein the liquid crystal display device is read from the storage means, and the at least two types of brightness adjustment signals are generated from the read color temperature information.