JPH1165531A - Image display device and lsi for image display - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image display device, capable of saving electric power while suppressing the deterioration of image by adjusting the emitted light quantity of a back light, in accordance with the allowance obtained by a data analyzing part. SOLUTION: When the maximum value of luminance data obtained by arithmetic operation shows a luminance '50', the value of a maximum luminance '100' divided by the maximum value '50' of the luminance data, i.e., 100/50=2 is obtained here. This value '2' representing allowance is inputted to a data- adjusting part 212 and a light control part 213, respectively, as an image data adjusting parameter and a luminance-adjusting parameter. The image data are also inputted to the data-adjusting part 212, and the inputted image data are adjusted according to the inputted image data adjusting parameter. Meanwhile, in the light control part 213, a backlight control signal for adjusting the emitted light quantity of the backlight 112 according to the inputted luminance adjusting parameter '2' is outputted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display screen such as a liquid crystal display screen in which each pixel shows a transmittance corresponding to data given to each pixel, and a backlight for illuminating the liquid crystal display screen from behind. The present invention relates to an image display device provided with the image display device, and an image display LSI incorporated in the image display device and controlling an image displayed on a liquid crystal display screen.

[0002]

2. Description of the Related Art In recent years, for example, a so-called notebook personal computer (hereinafter abbreviated as a notebook personal computer).
Image display devices having a liquid crystal display screen are widely used as image display devices in portable information devices. In such an image display device, the transmittance of the liquid crystal for each pixel of the liquid crystal display screen is adjusted based on the image data, and the liquid crystal display screen is illuminated from behind by a backlight, whereby the image is displayed on the liquid crystal display screen. Is displayed.

[0003]

Since the liquid crystal display screen is thin and compact, it is widely used for portable information equipment such as a notebook personal computer. However, a backlight consumes about 5 W of power, for example, and a notebook personal computer is used as an example. The power consumption of the notebook personal computer reaches about 1/4 to 1/2. Since portable information devices are generally configured to operate on batteries or the like, it is a major problem how to achieve power saving.

In order to reduce the power consumption of an image display device having a liquid crystal display screen, a backlight is provided for each of a plurality of divided areas of the liquid crystal display screen, and an image in the liquid crystal display screen is displayed. It has been proposed that the backlight in a non-existent area be turned off or the luminance lowered (Japanese Patent Laid-Open No. 3-1).
98026). Although such a method leads to power saving, the structure becomes complicated because it is necessary to provide a backlight for each area of the liquid crystal display screen, and the backlight is turned on for those who are observing the liquid crystal display screen It is difficult to make the boundary between the turned-on region and the turned-off region difficult to see, and if this boundary is conspicuous, the image quality of the entire image displayed on the liquid crystal display screen is significantly reduced.

[0005] In view of the above circumstances, the present invention provides an image display device in which power consumption is reduced while suppressing image degradation, and an image incorporated in the image display device and displayed on a display screen.
It is an object of the present invention to provide an image display LSI that performs control while saving power.

[0006]

An image display apparatus according to the present invention, which achieves the above object, comprises a display screen showing a transmittance corresponding to data given to each pixel by each pixel, and a backlight for illuminating the display screen from behind. An image display device comprising a light and displaying an image corresponding to the image data on a display screen, wherein the input image data is analyzed, and the image based on the input image data is displayed on the display screen. Data analysis means for obtaining the margin of the amount of light emitted from the backlight with respect to the luminance of the image, and image data adjustment for adjusting the input image data to image data corresponding to the transmittance higher by the margin obtained by the data analysis means And light control means for adjusting the amount of light emitted from the backlight in accordance with the margin obtained by the data analysis means.

The target display screen is, for example, an image as a luminance distribution when illuminated by a backlight by adjusting the transmittance of each pixel according to image data, as in the above-described liquid crystal display screen. Is displayed on the display screen. For example, even if a pixel is adjusted to have the highest transmittance in one image, the transmittance of the pixel is determined by data given to the pixel. In some cases, the transmittance is lower than the highest transmittance above. In such a case, the transmittance of the entire image is increased to a level where the transmittance of the pixel matches the highest transmittance in the performance of the liquid crystal, and the amount of light emitted from the backlight is reduced accordingly. By doing so, images with the same brightness can be provided, and power consumption can be reduced because the amount of light emitted from the backlight is suppressed.

Here, in the image display device of the present invention, image data representing a plurality of images is sequentially inputted,
In a case where a plurality of images are sequentially displayed on the display screen, the data analysis means uses the current image to be displayed on the liquid crystal display screen based on image data representing a previous image already displayed on the display screen or an image before the previous image. It is preferable to obtain the margin applied to

When the calculation of the margin in the data analysis means is performed based on image data representing an image to be displayed, the image data is stored during the calculation of the margin. Means are required. Usually, for example, on a liquid crystal display screen, about 70 images are displayed per second, which is faster than a human reaction speed. Therefore, even if the margin determined based on the image data representing a certain image is reflected in an image subsequent to the image, the margin is hardly affected by human eyes, and the image data for which the margin is determined is stored. Is no longer necessary,
An inexpensive device with a simple configuration can be configured.

In the image display apparatus of the present invention, the data analysis means extracts one pixel of data representing the highest transmittance from the image data representing one image, and extracts the data of one pixel. The margin of the amount of light emitted from the backlight with respect to the luminance of the displayed pixel may be obtained based on the data of one pixel when the image is displayed on the liquid crystal display screen.

In this case, even if the light emission amount of the backlight is reduced based on the obtained margin, an image having exactly the same brightness and exactly the same image quality can be obtained as compared with a case where such power saving measures are not taken. Can be provided. Alternatively, in the image display device according to the present invention, the data analysis unit obtains a histogram of data when image data representing one image is decomposed into data for each pixel, and based on the histogram, obtains the highest transmission. When a data range corresponding to the transmittance is obtained, and when the one image is displayed on a liquid crystal display screen, the luminance of a pixel displayed based on the data representing the lowest transmittance among the data included in the data range. The degree of margin of the amount of light emitted from the backlight may be obtained.

In this case, all the data included in the data range is adjusted to data corresponding to the same transmittance, and a part of the high luminance area of the image becomes an image having no luminance resolution. As a result, opportunities for lowering the amount of light emitted from the backlight are increased, and further power saving can be achieved. Further, in the image forming apparatus of the present invention, a control input terminal for inputting a control signal for switching whether or not to adjust the image data by the image data adjusting means and to adjust the amount of light emitted from the backlight by the light adjusting means. It is preferable to provide

In particular, when performing a process of replacing data included in a certain data range with data having the same transmittance as described above, an image having a high brightness resolution is obtained even in a part of a high brightness area in the image. A slight decrease in image quality is inevitable. Therefore, in such a case, if the control input terminal is provided, when a slight decrease in image quality is allowable, or when a slight decrease in image quality is unavoidable, power saving is performed, and when there is sufficient power, or Even when the image quality is not degraded, it can be switched so as not to perform power saving.

Here, the control signal input from the control input terminal substantially switches whether or not the adjustment of the image data by the image data adjusting means and the adjustment of the light emission amount of the backlight by the light adjusting means are performed. And the control signal does not have to directly act on the image data adjusting means and the dimming means. For example, if the control signal is a signal indicating that the adjustment of the image data and the adjustment of the amount of emitted light are not performed, the above-described data analysis means may determine that there is no room irrespective of the input image data. The margin to be expressed may be output. In this case, the image data adjusting means outputs the input image data as it is, and the dimming means does not perform the dimming of the backlight.

Further, the image display device of the present invention includes image data generating means for generating image data, and the image data generating means generates image data representing the same contents and representing images having different margins. It may be generated to be switchable. For example, when an image generated in a personal computer is displayed on a liquid crystal display screen, an image with a large margin is generated in the power saving mode according to the above-described control signal. Will be achieved.

Further, the image display LSI of the present invention that achieves the above object has a display screen showing a transmittance corresponding to data given to each pixel by each pixel, and a backlight for illuminating the liquid crystal display screen from behind. An image display LSI that is incorporated in an image display device that displays an image corresponding to image data on a display screen and controls an image displayed on the display screen analyzes the input image data, Data analyzing means for obtaining a margin of the amount of light emitted from the backlight with respect to the luminance of the image when an image based on the image data is displayed on the display screen; and input image data corresponding to the margin determined by the data analyzing means. Image data adjusting means for adjusting to image data corresponding to only high transmittance, and adjusting the amount of light emitted from the backlight according to the margin determined by the data analyzing means. Characterized in that a light control means for.

Conventionally, except for a configuration for power saving,
For example, an image display LSI for controlling an image displayed on a liquid crystal display screen is used. Therefore, by mounting the above-described configuration for power saving on the image display LSI, it is possible to configure a power-saving image display device with the same component configuration as in the related art. Easier,
This is advantageous for miniaturization and can reduce cost.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The principle of power saving of the present invention will be described below, and then the embodiments of the present invention will be described. FIG. 1 is a diagram for explaining the principle of power saving according to the present invention. FIG. 1A shows a state before power saving, and FIG. 1B shows a state after power saving. The horizontal axis in FIG. 1 shows pixels arranged in one line on the liquid crystal display screen.
The vertical axis indicates the luminance of each pixel.

When the data of a certain pixel is the data corresponding to the maximum transmittance of the liquid crystal, the luminance of the pixel given the data is "5" in consideration of the brightness of the backlight. . Here, as shown in FIG. 1A, since the luminance of the pixel A is “1”,
The transmittance of the pixel A is determined so that the light of the backlight is attenuated by the luminance '4' which is the difference between the luminance '5' and the luminance '1'. That is, the pixel A is given data that determines such transmittance.

Similarly, the luminance of the pixel B is “2”, which means that the pixel B has a luminance of “3” which is a difference between the luminance of “5” and the luminance of “2”. 'Means that the transmittance of the image B is determined so as to attenuate by'. That is, pixel B is given data that determines such transmittance. Similarly, the luminance of the pixel C is “4”, and the pixel C has a transmittance such that the light of the backlight is attenuated by the luminance “1” which is the difference between the luminance “5” and the luminance “4”. Is provided.

Here, it is assumed that the pixel C having a luminance of "4" is a pixel having the highest luminance over the entire area of the image.
In this case, in terms of the amount of light of the backlight and the capability of the transmittance of the liquid crystal, only the luminance of '4' is used although the luminance can be expressed up to '5'. Light is being blocked unnecessarily.

Therefore, as shown in FIG. 1B, data corresponding to pixel A, which was originally data for attenuating backlight light by luminance '4' as shown in FIG. The data is changed to data that attenuates by the luminance “3”.
Similarly, the data corresponding to the pixel B was originally data attenuated by the luminance “3”, but was changed to data attenuated by the luminance “2”, and the data corresponding to the pixel C was changed to the luminance “3”. The data which is attenuated by 1 'is changed to data corresponding to the maximum transmittance in view of the performance of the liquid crystal. As for image data, new image data is generated by adjusting the data value in the direction of increasing the transmittance of the liquid crystal over the entire surface of the image in this way,
As shown in FIG. 1B, that is, in the example shown here, the light emission amount of the backlight is reduced by the luminance of “1”. By doing so, power consumption can be reduced by reducing the amount of light emitted from the backlight, and an image having exactly the same luminance distribution can be displayed as compared to a case where such power saving is not performed.

Hereinafter, embodiments of the present invention will be described. FIG. 2 is an external view showing an example of a so-called notebook computer in which an embodiment of the image display device of the present invention further incorporating the embodiment of the image display LSI of the present invention is incorporated. It is a schematic diagram which shows a display screen and a backlight. The notebook computer 10 includes an image display unit 11 and a main body unit 12, which is an embodiment of the image display device of the present invention. The image display unit 11 includes a liquid crystal display screen 1
11, a backlight 112 for schematically illuminating the liquid crystal display screen 111 from the back, and a liquid crystal display screen 1 schematically shown in FIG.
Brightness adjustment knob 113 for manually adjusting the brightness of 1 (the amount of light emitted from the backlight 112);
A mode changeover switch 114 for normal mode changeover is provided. A keyboard 121 for giving various instructions to the notebook computer 10 is provided on the main body 12.
A pointing device 122 for designating an arbitrary point on the liquid crystal display screen 111;
A connector port 123 into which a connector of an adapter (not shown) is inserted, a floppy disk insertion port 124 for loading a floppy disk (not shown) into the notebook personal computer 10 are provided. A CPU, a hard disk, and a floppy disk drive for accessing a floppy disk inserted into the floppy disk insertion slot 124 are incorporated therein.
The notebook computer 10 has a built-in battery (not shown) and is operated by the battery. The notebook personal computer 10 is also configured to be operated by electric power supplied from a commercial power supply by inserting a connector of an AC adapter into the connector port 123. I have. When the connector of the AC adapter is inserted into the connector port 123, the insertion of the connector is detected inside the notebook computer, and the supply of power from the battery is cut off.

FIG. 4 is a block diagram focusing on a portion corresponding to the image display device of the present invention, which is configured inside the notebook personal computer 10 shown in FIG. The notebook personal computer 10 shown in FIG. 2 includes an image generating unit 201 configured by software.
Image data representing an image displayed on the liquid crystal display screen 111 is generated. The image generation unit 201 will be further described later.

The image data generated by the image generator 201 is temporarily stored in the image memory 202. Or
The notebook computer 10 can also insert a floppy disk storing image data into the floppy disk insertion slot 124 (see FIG. 2) and read image data from the floppy disk. Are temporarily stored in the image memory 202.

The image data read from the image memory 202 is input to an image display LSI 210. The image display LSI 210 includes a data analysis unit 211, a data adjustment unit 212, a light control unit 213, and an image controller 214.
15 are provided. The control input terminal 215 is an input terminal of a control signal for switching between the power saving mode and the normal mode. Here, it is assumed that the power saving mode is designated by the control signal.

The image data read from the image memory 202 is sent to the data analysis unit 211 of the image display LSI 210.
Is input to Here, the image data is RGB (Re
d, Green, Blue), and the liquid crystal display screen 111 has 640 pixels by 480 pixels per color. Therefore, the image data for one image is 64 pixels.
It is a set of 0 × 480 × 3 = 921600 luminance data.

In this embodiment, the data analyzer 211 detects the maximum value of the luminance data for one image. This maximum value is, when an image is displayed on the liquid crystal display screen 111,
It corresponds to the maximum luminance (highest transmittance) on the image. FIG. 5 is a flowchart illustrating a flow of the maximum value detection in the data analysis unit.

Here, i is a variable as a counter, K
(I), i = 1, 2,..., 921600 represent 921,600 pieces of luminance data representing one image, and P represents a variable for storing the maximum value. First, the initial value 1 is set in the counter i (step (a)), and the luminance data K is set.
(I) (here, K (1)) is stored in the variable P (step (b)). Next, the counter i is incremented (step (c)), and a magnitude comparison between P and K (i) is performed (step (d)). When P <K (i), K is determined.
After (i) is set to P (step e)), P ≧
In the case of (i), the process directly proceeds to step (f). In step (f), it is determined whether or not the counter i has reached 921,600. If it has not yet reached, the process returns to step (c). When i has reached 921,600, this routine is exited. The variable P at the time of exiting this routine stores the maximum value _Pmax of 921,600 pieces of luminance data.

Returning to FIG. 4, the description will be continued. Here, the maximum value of the luminance determined by a combination of the maximum transmittance of the liquid crystal constituting the liquid crystal display screen 111 and the amount of light emitted from the backlight is "100". Note that the amount of light emitted from the backlight can be adjusted by using the brightness adjustment knob 113 shown in FIG.
The maximum value of the luminance determined by the combination of the maximum amount of light emitted from the backlight after the adjustment in and the maximum transmittance of the liquid crystal is "100".

At this time, the maximum value _Pmax of the luminance data obtained by the calculation described with reference to FIG.
When “0” is indicated, the data analysis unit 211 obtains a value obtained by dividing the maximum luminance “100” by the maximum value “50” of the luminance data, that is, 100/50 = 2 here.
The value “2” is input to the data adjustment unit 212 and the dimming unit 213 as an image data adjustment parameter and a brightness adjustment parameter, respectively, which indicate the margin in the present invention. Image data is also input to the data adjustment unit 212, and the input image data is adjusted in the data adjustment unit 212 according to the input image data adjustment parameters. That is, in the example shown here, “2” which is an image data adjustment parameter is added to each of a large number of pieces of luminance data forming the input image data, and each of the pieces of luminance data has a luminance twice as large. Adjusted to data. This means that if the amount of light emitted from the backlight is not changed, the brightness of the image displayed on the liquid crystal display screen 111 is twice as high in any pixel.

On the other hand, in the light control section 213, the amount of light emitted from the backlight 112 is adjusted by manually turning the brightness adjustment knob 113 (see FIG. 2) according to the input brightness adjustment parameter '2'. A backlight dimming signal for adjusting the amount of emitted light is output such that the amount of emitted light is obtained by dividing the maximum amount of emitted light of the backlight by the luminance adjustment parameter '2'. The backlight dimming signal output from the dimming unit 213 is input to the inverter circuit 116 for causing the backlight 212 to emit light. The inverter circuit 116 generates power according to the backlight dimming signal and supplies the generated power to the backlight 112, and the backlight 112 emits light with an amount of light corresponding to the supplied power.

On the other hand, the image data adjusted by the data adjustment unit 212 is input to the image controller 214,
The image is converted into a driver driving signal for driving the liquid crystal driver 115 by the image controller 214 and supplied to the liquid crystal driver 115. The liquid phase driver 115 is a circuit for driving the liquid crystal of each pixel constituting the liquid crystal display screen 111 to determine the transmittance of each pixel. Is irradiated, an image as a luminance distribution is displayed on the liquid crystal display screen 111.

Here, as described above, the data adjustment unit 2
12, the image data is adjusted so that the luminance of each pixel is doubled when the light amount of the backlight is not changed in the example here.
That is, in this example, the adjustment is performed so that the amount of light of the backlight is reduced to half. Therefore, the liquid crystal display screen 1
11 shows an image which is no different from the case where the adjustment of the image data and the adjustment of the light amount of the backlight are not performed.

Here, a cold cathode tube is usually used as the backlight, and consumes about 5 W of electric power. On the other hand, the liquid crystal driver 115 consumes about 0.5 W of power and consumes little power. Therefore, by adjusting the image data and the light amount of the backlight as described above, the power consumption of the entire notebook personal computer (see FIG. 2) can be reduced.

Conventionally, a notebook personal computer or the like controls the liquid crystal driver 115 and the inverter circuit 116 by taking data from an image memory into an image control LSI and performing processing. In the present embodiment, since the image display LSI 210 having the electronic saving function having the configuration shown in FIG. 4 is provided, the same component configuration as that of a conventional image display apparatus without such a power saving function can be obtained. Other components except for the image display LSI can be shared with the image display device, and the device design is easy, which contributes to downsizing and cost reduction.

Here, in the image display device shown in FIG. 4, a large number of image data are sequentially input to the image memory so that about 70 images are sequentially displayed on the liquid crystal display screen 111 per second. These many image data are sequentially read from the image memory 202, or, in the case of a still image, the image data once stored in the image memory 202 is repeatedly read.

Here, the images (image data) sequentially input to the data analysis unit 211 are sequentially input in order of n, n + 1, n +
Called 2, ... The data analysis unit 211 attempts to reflect the result of the data analysis performed on the image n on the image n, until the data analysis is completed.
Need to be stored once without being displayed. Therefore,
Here, the result of performing the data analysis on the image n is reflected on the next input image n + 1,
The result of data analysis for +1 is further reflected on the next input image n + 2. As described above, an image is displayed on the liquid crystal display screen 111 at a speed higher than the response speed of the human eye (about 70 images per second). (Referring to the image following the previous image) has little effect on the image quality and the degree of power saving, and by doing so, there is no need to store images during data analysis. Such an image storage memory is not required.

Here, it has been described that the data analysis result of the image just one image before is reflected in the next image.
Alternatively, the data analysis result of the image three images before may be reflected, or the average value of the data analysis results of a plurality of previously input images may be reflected. Next, another data analysis method in the data analysis unit 211 will be described.

FIG. 6 is a diagram showing an example of a histogram of many pieces of luminance data representing one image. In the above-described embodiment, the maximum value P _max of the luminance data is obtained by the data analysis unit 211. Here, the luminance value P1 having an appearance frequency of 5% is obtained from the maximum value P _max of the luminance data.
This luminance value P1 is set to the maximum value P in the above-described embodiment.
_The image data adjustment parameter and the brightness adjustment parameter are obtained in the same manner as _max . At this time,
In the data adjustment unit 212, the luminance data included in the data range sandwiched between the maximum value _Pmax and the luminance value P1 is all
Adjusted to the same value corresponding to the maximum transmittance of the liquid crystal, each luminance data within this data range results in a loss of luminance resolution on the image displayed on the liquid crystal display screen 111. Instead, the dimming of the backlight is also the maximum value P
_Since the adjustment is performed based on the brightness value P1 instead of the maximum value, the amount of light emitted from the backlight can be further reduced as compared with the case where dimming is performed based on the maximum value _Pmax , and further power saving can be achieved. become.

In the above description, the point at which the appearance frequency of the luminance data is 5% from the maximum value _Pmax side is described as the luminance value P1 serving as a reference for obtaining a parameter. However, the present invention is not limited to 5%. The fact that the data range sandwiched between the maximum value _Pmax and the luminance value P1 has no luminance resolution makes the liquid crystal display screen 111 inconspicuous on the displayed image and achieves sufficient power saving. It is desirable to set the degree, and for example, a knob similar to the luminance adjustment knob 113 shown in FIG. 2 may be prepared so that the user can adjust the degree.

FIG. 7 is a diagram showing an example of an image displayed on the liquid crystal display screen 111. Image generation unit 2 shown in FIG.
01, for example, image data representing an image as shown in FIG. 7 is generated. In the normal mode which is not the power saving mode, it is assumed that the characters “ABC...” 111a are white characters and the background 111b is blue. In the power saving mode, the characters “ABC...”
1a is changed to gray, and the background 111b is changed to black in order to maintain the luminance difference from the character. As described above, the image generation unit 201 expresses the same contents in the normal mode and the power saving mode, and changes the color setting in the power saving mode so that the brightness of the image is lower than that in the normal mode. By doing so, in the power saving mode, larger parameters are obtained for the image data adjustment parameter and the brightness adjustment parameter, and further power saving is achieved.

Next, switching between the power saving mode and the normal mode will be described. As described above, the image display LSI 210 shown in FIG. 4 includes the control input terminal 215 for inputting a mode switching control signal. When a control signal designating the power saving mode is input to the control input terminal 215, as described above, the liquid crystal display screen 1
The emission amount of the backlight 112 is reduced while maintaining the image quality of the image displayed on the display 11 as much as possible. On the other hand, when a control signal designating the normal mode is input to the control input terminal 215, the image generation unit 201
In addition to the generation of the image for the normal mode as described above, the data analysis unit 211 generates “1” as the image data adjustment parameter and the luminance adjustment parameter regardless of the input image data, and performs data adjustment. Part 212
And to the adjustment unit 213. Then, the data adjustment unit 212 outputs the input image data directly to the image controller 214, and the light adjustment unit 213 outputs
Dimming of the backlight is not performed except for the case where the user manually adjusts the brightness by turning the brightness adjustment knob 113 (see FIG. 2). By doing so, an image as before, particularly without power saving, is displayed on the liquid crystal display screen 111.

FIG. 4 illustrates various control signal generating means for generating a control signal for switching between the power saving mode and the normal mode. For example, when using an application program that does not allow image quality degradation, stop the power saving mode from the application program and switch to the normal mode. When using an application program that allows image quality degradation, use the application program in the power saving mode. The control signal is switched by the software signal 301 so that the moodware switch 11 shown in FIG.
4 is manually switched by the user.
When the C adapter is attached, the power is abundant and the mode is switched to the normal mode. When the AC adapter is not attached, the mode is switched to the power saving mode to save valuable power from the battery. Change detection unit 203
Thus, the change in the capacity of the battery operating the notebook personal computer 10 (see FIG. 2) is detected, and the mode is switched to the normal mode when the battery capacity is sufficient and to the power saving mode when the battery capacity decreases. If the control path force terminal 215 is provided, the power saving mode and the normal mode can be switched by various triggers as illustrated in FIG.

In this embodiment, the configuration for switching between the normal mode and the power saving mode has been described. However, such mode switching is not always necessary, and the apparatus is designed to always operate the power saving mode. You may comprise.
Even in that case, for example, described with reference to FIG.
When the image data adjustment parameter and the luminance adjustment parameter are obtained based on the maximum value _Pmax of the luminance data, there is no deterioration in image quality, or the method described with reference to FIG. Even in the case where is adopted, it is also possible to always operate the circuit for power saving by devising such that the degree of the deterioration can be adjusted by the user.

[0046]

As described above, according to the present invention,
An image display device in which power consumption is reduced while suppressing deterioration of image quality, and an image display LSI having a power saving function of the image display device are configured.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the principle of power saving according to the present invention.

FIG. 2 is an external view showing an example of a so-called notebook personal computer in which an embodiment of an image display device of the present invention further incorporating an embodiment of an image display LSI of the present invention is incorporated.

FIG. 3 is a schematic diagram showing a liquid crystal display screen and a backlight.

FIG. 4 is a block diagram focusing on a portion corresponding to the image display device of the present invention, which is configured inside the notebook personal computer shown in FIG. 2;

FIG. 5 is a flowchart illustrating a flow of detecting a maximum value in a data analysis unit.

FIG. 6 is a diagram illustrating an example of a histogram of a large number of luminance data representing one image.

FIG. 7 is a diagram illustrating an example of an image displayed on a liquid crystal display screen.

[Explanation of symbols]

 REFERENCE SIGNS LIST 10 notebook computer 11 image display section 12 main body section 111 liquid crystal display screen 112 backlight 113 brightness adjustment knob 114 mode changeover switch 115 liquid crystal driver 116 inverter circuit 121 keyboard 122 pointing device 123 connector port 124 floppy disk insertion port 201 image generation section 202 image Memory 210 Image display LSI 211 Data analysis unit 212 Data adjustment unit 213 Light control unit 214 Image controller 215 Control input terminal 301 Software signal 302 AC adapter attachment / detachment detection unit 303 Battery capacity change detection unit

Claims (7)

[Claims] An image display device according to claim 1, further comprising: a display screen showing a transmittance corresponding to data given to each pixel by each pixel; and a backlight for illuminating the liquid crystal display screen from the back side. In the image display device, the input image data is analyzed, and the margin of the light emission amount of the backlight with respect to the luminance of the image when an image based on the input image data is displayed on the display screen is displayed. Data analysis means for obtaining the image data, image data adjustment means for adjusting the input image data to image data corresponding to the transmittance higher by the margin obtained by the data analysis means, and the light emission amount of the backlight An image display device comprising: a light control unit that adjusts according to the margin obtained by the data analysis unit. 2. In a case where image data representing a plurality of images are sequentially input and a plurality of images are sequentially displayed on the display screen, the data analysis means may include a previous image already displayed on the display screen or the previous image. 2. The image display device according to claim 1, wherein a margin to be applied to a current image to be displayed on the display screen is obtained based on image data representing a previous image. 3. The method according to claim 1, wherein the data analyzing unit extracts one pixel of data representing the highest transmittance from image data representing one image and displays the one image on the display screen. An image display device for obtaining a margin of a light emission amount of the backlight with respect to a luminance of a pixel displayed based on the data of one pixel. 4. A data range in which the data analysis unit obtains a histogram of data when image data representing one image is decomposed into data for each pixel, and associates the histogram with the highest transmittance based on the histogram. And the said 1
When displaying one image on the liquid crystal display screen, the margin of the amount of light emitted from the backlight with respect to the luminance of the pixel displayed based on the data representing the lowest transmittance among the data included in the data range. 2. The image display device according to claim 1, wherein: 5. A control input terminal for inputting a control signal for switching whether or not adjustment of image data by the image data adjusting means and adjustment of the amount of light emitted from the backlight by the light adjusting means are performed. The image display device according to claim 1, wherein: 6. An image data generating means for generating image data, wherein the image data generating means switches and generates image data expressing the same contents and representing images having different margins. The image display device according to claim 1, wherein: 7. A display screen showing a transmittance according to data given to each pixel by each pixel, and a backlight for illuminating the liquid crystal display screen from behind, displaying an image corresponding to the image data on the display screen. Image display LSI incorporated in an image display device for controlling the image displayed on the display screen
A data analysis unit that analyzes input image data and obtains a margin of a light emission amount of the backlight with respect to a luminance of the image when an image based on the input image data is displayed on the display screen. An image data adjustment unit that adjusts the input image data to image data corresponding to a transmittance higher by the margin obtained by the data analysis unit; and an emission light amount of the backlight, the data analysis unit An image display LSI comprising: a light control unit that adjusts according to the obtained margin.