JPH09288262A - Liquid crystal display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid crystal display device in which the rising characteristic of luminance at the time of a low temp. is improved while suppressing the raising of the cost of a device. SOLUTION: A temp. control part 7 outputs a control DC voltage 72 in accordance with the detection result of a thermistor 4. A brightness control part 8 outputs an adjustment signal 80 according to the control DC voltage 72. An inverter circuit 10 supplies an AC voltage to a back light 3 with a duty ratio specified by a control signal by turning the input of a DC voltage 90 on and off according to the adjustment signal 80. When the temp. of the back light is low. the inverter circuit 10 makes the duty ratio high and makes the ratio low when the temp. of the back light 3 is made to be sufficiently high (equal to or higher than a normal temp.).

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 provided with a lighting element such as a backlight.

[0002]

2. Description of the Related Art Liquid crystal display devices have the problem that the screen becomes dark at low temperatures. Therefore, various techniques have been studied so far in order to improve this problem.

For example, Toshiba Review (1991. Vol. 46 No.
12) discloses a technique in which a heater is provided in the backlight and the heater is energized at low temperatures to improve the brightness rising characteristics at low temperatures. The temperature of the backlight is detected by a temperature sensor provided separately.

Technical Report of Television Society (Vol.18 No19
(March 18, 1994) discloses a technique for performing brightness compensation by fixing the brightness to the maximum value at low temperature. The brightness adjustment uses a function for the customer to adjust the brightness.

In addition to this, by controlling the input DC voltage of the inverter according to the temperature instead of the heater,
Techniques have been proposed for improving the brightness rise at low temperatures. The temperature of the backlight is detected by a temperature sensor provided separately.

[0006]

However, the use of the heater causes a large increase in the cost of the apparatus. In addition, a heater must be attached to the backlight tube itself for efficient heating. However, if a heater is attached to the backlight tube itself, the light transmittance is lowered, and there is a problem in that it adversely acts at room temperature. Further, a power source for the heater is required.
A portable information device, which is a main application of a liquid crystal display device, is assumed to be driven by a battery, and its power supply capacity is limited. Therefore, the increase in power consumption has been a big problem.

In terms of performance, the inverter power supply control can be expected to have the same effect as the heater system. However, in order to change the DC voltage for the inverter, the size of the transformer of the inverter device must be increased, and the device cost is increased.

The method of responding by adjusting the brightness does not aim to solve the problem of the liquid crystal display device. Therefore, the brightness rising performance at low temperatures was significantly inferior to the above-mentioned conventional technique using a heater or the like. In order to obtain the same effect as when using a heater or the like, it is necessary to increase the current to the backlight even at room temperature. This has another problem that the life of the backlight is shortened as a result.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a liquid crystal display device having improved brightness rising characteristics at low temperatures without causing an increase in device cost.

[0010]

The present invention has been made to achieve the above object, and a first aspect thereof is a liquid crystal display panel, a backlight for illuminating the liquid crystal display panel, and the backlight. Temperature detection means for detecting the temperature of the light, a control circuit for generating a control signal designating the duty ratio of the voltage supply to the backlight, and a voltage to the backlight with a duty ratio according to the control signal. And a voltage supply circuit for
There is provided a liquid crystal display panel characterized in that the value of the control signal is changed according to the detection result of the temperature detecting means.

The control means has a predetermined reference temperature, the duty ratio when the temperature of the backlight is lower than the reference temperature, and the duty ratio when the temperature of the backlight is higher than the reference temperature. It is preferable to make it lower than the duty ratio.

It is preferable that the control means lower the duty ratio designated by the control signal as the temperature of the backlight is lower within a predetermined temperature range. In this case, it is preferable that the control means linearly changes the duty ratio designated by the control signal within the predetermined temperature range in accordance with the temperature of the backlight.

The voltage supply circuit includes a constant voltage circuit for converting an AC voltage serving as a power source into a DC voltage and outputting the DC voltage, an inverter circuit for converting the DC voltage into an AC voltage and supplying the backlight, and the control signal. Accordingly, it is preferable to include switching means for turning ON / OFF the input of the DC voltage to the inverter circuit.

The operation will be described.

The temperature detecting means detects the temperature of the backlight.

The control circuit generates and outputs a control signal designating a duty ratio according to the detection result of the temperature detecting means (that is, the temperature of the backlight). For example, the duty ratio when the temperature of the backlight is lower than the reference temperature is set lower than the duty ratio when the temperature of the backlight is higher than the reference temperature. Further, within the predetermined temperature range, the lower the backlight temperature, the lower the duty ratio.

The voltage supply circuit supplies a voltage to the backlight with a duty ratio according to the control signal. Thereby, when the temperature of the backlight is low, sufficient brightness can be secured. Further, since the amount of heat generated is large, the temperature can be raised quickly. After the temperature has risen sufficiently,
By appropriately lowering the duty ratio, it is possible to prevent the brightness from becoming too high. It also prevents the temperature from becoming too high.

Such voltage supply can be performed by the switching means turning ON / OFF the input of the DC voltage output from the constant voltage circuit to the inverter circuit in accordance with the control signal.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to the drawings.

The liquid crystal display device of this embodiment comprises a liquid crystal display unit 1, a temperature control unit 7, a brightness control unit 8, a constant voltage circuit 9 and an inverter circuit 10.

The liquid crystal display unit 1 comprises a liquid crystal plate 2, a backlight 3, a thermistor 4, a diffusion plate 5 and a reflection plate 6.

The liquid crystal plate 2 displays according to the display signal from the image display circuit 11 provided separately. The liquid crystal plate 2 and the image display circuit 11 themselves have nothing to do with the essence of the present invention, and since they are well known techniques, detailed description thereof will be omitted.

The backlight 3 illuminates the liquid crystal plate 2 from the back side. The liquid crystal plate 2 includes an inverter circuit 10
It is turned on by the AC voltage input from. In this embodiment, a cold cathode tube is adopted as the backlight 3. The cold cathode tube changes its light emission amount and heat generation amount according to the duty ratio of the input voltage. Therefore, in the present embodiment, by utilizing this characteristic, the duty ratio of the input voltage from the inverter circuit 10 is controlled to adjust the light emission amount and the heat generation amount.

The thermistor 4 is for detecting the temperature of the backlight 3 and is installed on the surface of the backlight 3. In the present embodiment, as the thermistor 4, a thermistor output voltage 40 that changes linearly according to the temperature of the backlight 3 is adopted. The thermistor 4 outputs the thermistor output voltage 40, which is the detection result,
It is output to the temperature control unit 7.

The temperature control unit 7 has a thermistor output voltage 40
The control DC voltage 72 for adjusting the duty of the inverter circuit 10 according to (that is, the temperature of the backlight 3) is generated and output. The temperature control unit 7 is provided with a map or a relational expression describing the relation between the detection result of the thermistor 4 (the temperature of the backlight 3) and the control DC voltage 72. The temperature control unit 7
Determines the value of the control DC voltage 72 by referring to the map or the like. The contents of this map and the like are predetermined in consideration of the relationship between the duty ratio (control DC voltage 72) and the heat generation amount and brightness of the backlight 3. An example of the correspondence described in this map is shown in FIG. The contents of FIG. 3 will be described later together with the operation. In this embodiment, the temperature control unit 7 is composed of a memory, a program and data stored in the memory, a microcomputer 70 that executes the program, and the like.

The brightness control section 8 outputs an adjustment signal 80 for adjusting the duty ratio to the inverter circuit 10 according to the control DC voltage 72 input from the temperature control section 7 and the brightness setting instruction (not shown) set by the user. Is output to.

Constant voltage circuit 9 and inverter circuit 10
Is a backlight 3 using an AC voltage input separately.
Is for lighting. The constant voltage circuit 9 converts the separately input AC voltage into a DC voltage and then outputs the DC voltage. The inverter circuit 10 converts the DC voltage 90 input from the constant voltage circuit 9 into AC of a predetermined frequency and outputs it to the backlight 3. Inverter circuit 10 of the present embodiment
According to an instruction from the brightness control section 8, the input of the DC voltage 90 from the constant voltage circuit 9 can be turned ON / OFF. In this way, turn on / off the DC voltage 90 input.
By performing F, the inverter circuit 10 causes the backlight 3
The duty ratio of the AC voltage output to is adjusted.

FIG. 2 shows a concrete circuit configuration of each section described above.
It was shown to. The brightness controller 8 is composed of a digital oscillator circuit. ON / OFF of the input of the DC voltage 90 in the inverter circuit 10 described above is performed by the transistor 10
Done by 0.

The operation will be described.

It is assumed that the user has not changed the brightness adjustment value during the operation described below.

The inverter circuit 10 converts the DC voltage 90 supplied from the constant voltage circuit 9 into AC of a predetermined frequency and supplies it to the backlight 4.

The thermistor 4 outputs a thermistor output voltage 40 according to the temperature of the backlight 3. The temperature controller 7 outputs a control DC voltage 72 according to the thermistor output voltage 40 to the brightness controller 8. The brightness control unit 8 outputs to the inverter circuit 10 an adjustment signal 80 of the duty ratio according to the control DC voltage 72 and the user setting value at that time. Inverter circuit 10
Turns on the input of the DC voltage 90 according to the adjustment signal 80.
By turning on / off, the duty ratio of the AC voltage supplied to the backlight 3 is adjusted.

A concrete example of setting the duty ratio according to the temperature of the backlight 3 is shown in FIG.

The thermistor output voltage 40 changes linearly according to the temperature of the backlight 3.

When the temperature of the backlight 3 is low (here, 25 ° C. or lower), the temperature control section 7 changes the value of the control DC voltage 72 to set the duty ratio to 100% to 50%. Change in between. As described above, when the duty ratio is kept constant, the lower the temperature of the backlight 3, the lower the brightness. Therefore, the lower the temperature, the higher the duty ratio. By increasing the duty ratio, not only the brightness is increased but also the amount of heat generated is increased. This also speeds up the temperature rise of the backlight 3.

When the temperature of the backlight 3 rises (here, at 25 ° C. or higher), the temperature controller 7 changes the value of the control DC voltage 72 to reduce the duty ratio. At this time, the temperature is already high enough,
Even if the duty ratio is reduced, sufficient brightness can be obtained. Also,
Since the amount of heat generation is also reduced by lowering the duty ratio, the temperature of the backlight 3 does not become higher than necessary.

Here, the content of the duty ratio control is changed with reference to 25 ° C. However, it goes without saying that this specific temperature can be appropriately selected according to the performance of the backlight 3 used. The same applies to specific values of the duty ratio at each temperature.

According to the above-described embodiment, it is possible to improve the reduction in brightness at low temperatures and to quickly raise the temperature. Also, the device cost can be suppressed.

Table 1 shows the results of performance and cost comparison between the liquid crystal display device to which the present invention is applied and the conventional device. The numerical values shown in Table 1 are obtained by scoring the performance and the cost according to the separately determined standard.

[0040]

[Table 1]

As can be seen from Table 1, when the performance and the cost are individually examined, some of the conventional techniques have the same scores as those of the present invention. However, the total point was highest in the technique of the present invention, and it was clarified that the present invention is superior when viewed comprehensively.

The "temperature detecting means" referred to in the claims means the thermistor 4 in the above embodiment.
Is equivalent to The “control circuit” corresponds to the temperature control unit 7. The “power supply circuit” corresponds to the constant voltage circuit 9, the inverter circuit 10, and the brightness control unit 8. The “control signal” corresponds to the control DC voltage 72. The “constant voltage circuit section” corresponds to the constant voltage circuit 9. The “inverter circuit section” means the transistor 1 in the inverter circuit 10.
It corresponds to the part other than 00. The “switching means” corresponds to the brightness controller 8 and the transistor 100.

However, the above-mentioned units operate in close cooperation with each other, and the definition described here is not strict. For example, the brightness control unit 8 can be considered to be included in the “control circuit” instead of the “power supply circuit”. In this case, the adjustment signal 80 corresponds to the "control signal".

[0044]

As described above, according to the present invention, it is possible to provide a liquid crystal display device in which the rise of brightness at low temperature is improved without inviting an increase in device cost. In addition, there is no reduction in brightness at room temperature and shortening of device life.

[Brief description of drawings]

FIG. 1 is a diagram showing an overall configuration of an embodiment of the present invention.

FIG. 2 is a diagram showing a specific circuit configuration.

FIG. 3 is a diagram showing a relationship between temperature and an output voltage value and an output voltage waveform in each part of the device.

[Explanation of symbols]

1 ... Liquid crystal display part, 2 ... Liquid crystal plate, 3 ... Backlight, 4 ...
Thermistor, 5 ... Diffuser, 6 ... Reflector, 7 ... Temperature controller, 8 ... Luminance controller, 9 ... Constant voltage circuit, 10 ... Inverter circuit, 11 ... Image display controller, 40 ... Thermistor output voltage, 70 ... Microcomputer, 72 ... Control DC voltage,
80 ... Adjustment signal, 90 ... DC voltage, 100 ... Transistor, 102 ... Inverter output voltage

Claims (5)

[Claims] 1. A liquid crystal display panel, a backlight for illuminating the liquid crystal display panel, temperature detecting means for detecting the temperature of the backlight, and a control signal designating a duty ratio of voltage supply to the backlight. And a voltage supply circuit that supplies a voltage to the backlight at a duty ratio according to the control signal, and the control circuit changes the value of the control signal according to the detection result of the temperature detecting means. A liquid crystal display panel characterized by being changed. 2. The control means comprises a predetermined reference temperature, wherein the duty ratio when the temperature of the backlight is lower than the reference temperature, and when the temperature of the backlight is higher than the reference temperature 2. The liquid crystal display device according to claim 1, wherein the duty ratio is lower than the duty ratio in. 3. The control means lowers the duty ratio designated by the control signal as the temperature of the backlight is lower within a predetermined temperature range. Item 3. A liquid crystal display device according to item 1. 4. The control means linearly changes the duty ratio designated by the control signal within the predetermined temperature range according to the temperature of the backlight. The liquid crystal display device according to claim 3. 5. The voltage supply circuit, a constant voltage circuit for converting an AC voltage serving as a power source into a DC voltage and outputting the DC voltage, an inverter circuit for converting the DC voltage into an AC voltage and supplying the backlight. 5. The liquid crystal display device according to claim 1, comprising switching means for turning ON / OFF the input of the DC voltage to the inverter circuit according to a control signal.