JP2003280598A - Device, method, program for displaying image, and computer readable recording medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To correct contrast by considering a diffusion component other than the transmitting component of a back surface transmitting light, and the reflection component of an outer environmental light. <P>SOLUTION: An image display device performs transflective display by the back surface transmitting light and the outer environmental light. The device includes: an input part (1) for inputting image data; an illuminance detecting part (2) for detecting illuminance by the outer environmental light; a correction curve setting part (5) for setting a correction curve, which is decided by relation between illuminance and contrast in the case of existence of the component other than the transmitting component of the back surface transmitting light and the reflection component of the outer environmental light, and by which the contrast of image data is corrected based on the detected illuminance; a data converting part (6) for converting image data based on the set correction curve; and a display panel (7) for performing transflective display in converted image data. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image display device, an image display method, an image display program, and a computer-readable recording medium for performing semi-transmissive reflection display by rear transmitted light and external ambient light.

[0002]

2. Description of the Related Art Conventionally, a transflective liquid crystal display (L
CD: Liquid Crystal Display)
The panel is known. Figure 6 shows a transflective LCD
An example of a panel is shown. In FIG. 6, the left side shows the light generation mechanism when displaying white on the LCD, and the right side shows the light generation mechanism when displaying black. The LCD functions as a shutter for incident light and backlight light, and displays white and black. The semi-transmissive reflection plate has a structure in which a hole is provided in a part of a metal reflection plate and reflects a part of incident light and transmits a part of backlight light.

[0003]

A liquid crystal panel (LC) which performs a semi-transmissive reflection display by rear transmitted light and external ambient light.
In D), the transmission component due to the rear surface transmitted light, the reflection component due to the external environment light, and the other components contribute to the generation of light. The light transmittance, the diffuse reflection coefficient, and other scattering components are different between white and black.

In this specification, this scattering component is referred to as "LCD.
The components other than the above-mentioned transmission component and reflection component inside "are defined. The present inventor has experimentally determined that a white scattering component (Do
It was confirmed that n (I)) was not a constant value, but increased monotonically as the illuminance I increased. That is, the white light generation model can be expressed by the following equation.

[0005]

[Equation 1]

However, _TON is the light [c
d / m2], _RON is the light due to the reflected component [cd / m
2] and D _ON (I) are the amount of light increase [cd / m 2] due to the scattering component when ON, and when D _ON (I)> 0, the increase increases monotonically.

Further, t _ON is the light transmittance when ON, r
_ON is a diffuse reflection coefficient [cd / m2 / l when ON]
x] and L are backlight light [cd / m2], and I is illuminance [lx].

Further, the present inventor has confirmed by experiments that the black scattering component (Doff (I)) takes a negative value and decreases monotonically as the illuminance I increases, not at a constant value. The black light generation model can be expressed by the following equation.

[0009]

[Equation 2]

However, T _OFF is light due to a transmitted component [cd / m2], and R _OFF is light due to a reflected component [cd].
/ M2], D _OFF (I) is the light increase [cd / m2] due to the scattering component when OFF, and D _OFF (I) <
At 0, there is a monotonic decrease with increasing I.

Further, t _OFF is the light transmittance when _OFF , and r _OFF is the diffuse reflection coefficient [cd / m when OFF.
2 / lx], L is the backlight light [cd / m2], I
Is the illuminance [lx].

The white display brightness, the black display brightness, and the contrast when these scattering components are present, that is, the white brightness / black brightness are as shown in FIGS. 7 and 8. FIG. 7 shows, from the left side, white display brightness, black display brightness, and contrast when there is no scattered component. In addition, FIG. 8 shows white display brightness, black display brightness, and contrast when a scattering component is present, from the left side. The parameters are as follows: T _ON : 0.01, R _ON : 5.09, L: 1500, T _OFF : 0.0008, R _OFF : 0.45

The relationship between D _ON (I) and D _OFF (I) due to the scattered component and the illuminance is as follows.

[0014]

[Table 1] Comparing FIG. 7 and FIG. 8, regarding the display brightness of white and the display brightness of black, the display brightness also increases as the illuminance increases regardless of the presence or absence of the scattered component.

However, regarding the contrast shown on the rightmost side of both figures, when the illuminance is high, the contrast is low when there is no scattered component, but when the illuminance is high, the contrast is high when the scattered component is present. Is also getting higher. That is, the relationship between the illuminance and the contrast is completely different depending on the presence or absence of the scattered component. Therefore, if the relationship between illuminance and contrast changes depending on the presence or absence of these scattering components, it is considered necessary to change the correction curve when displaying an image according to the illuminance.

The present invention is directed to an image display device, an image display method, an image display program, and a computer-readable record for performing contrast correction in consideration of a scattered component other than a transmitted component of rear transmitted light and a reflected component of external ambient light. The purpose is to provide a medium.

[0017]

An image display device of the present invention is an image display device for performing semi-transmissive reflection display by rear transmitted light and external environment light, and an input section for inputting image data and the external environment. An illuminance detection unit that detects illuminance due to light, is determined from the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the back transmitted light and the reflected component of the external ambient light, and based on the detected illuminance. A correction curve setting unit that sets a correction curve for correcting the contrast of the image data, a data conversion unit that converts the image data based on the set correction curve, and a semi-transmissive reflection of the converted image data. A display panel for displaying is provided.

With this configuration, it is possible to set the correction curve based on the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light according to the illuminance. Therefore, it is possible to perform the display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

Further, in the image display device of the present invention, the correction curve has a higher contrast as the illuminance becomes higher when a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light is present. It is characterized by being determined based on the relationship between the illuminance and the contrast.

The inventor of the present invention has found by experiments that when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light, the contrast increases as the illuminance increases. By determining the correction curve based on this relationship, it is possible to perform display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

Further, in the image display device of the present invention, the correction curve setting section sets the correction curve when the detected illuminance is lower than a reference value, and when the detected illuminance is higher than the reference value. Is characterized by setting a correction curve without contrast correction.

The present inventor has found by experiments that the contrast increases as the illuminance increases when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. That is, when the illuminance is high, the contrast is also high, so that it is not particularly necessary to correct the contrast. Therefore, when the illuminance is higher than the reference value, a correction curve that does not correct the contrast is set. As a result, natural gradation expression can be performed. On the other hand, when the illuminance is lower than the reference value, the contrast also becomes low. In this case, therefore, a correction curve for correcting the contrast is set. This makes it possible to perform high-contrast display even when the illuminance is low.

Further, in the image display device of the present invention, the correction curve setting unit determines a ratio between the correction curve and a correction curve in which contrast is not corrected according to the detected illuminance, and based on the ratio. A feature is that a correction curve is set by combining the correction curve and a correction curve that does not correct the contrast.

Since the gradation characteristics continuously change with changes in illuminance, as described above, the correction curve for contrast correction and the correction curve for no contrast correction are set based on the ratio according to the illuminance. Set the combined correction curve. This makes it possible to avoid a sudden change in the gradation setting with a certain illuminance as a boundary. Further, even when the illuminance changes frequently, it is possible to perform an appropriate display without making the user feel uncomfortable.

Further, in the image display device of the present invention, the illuminance detecting section includes a sensor for automatically detecting the illuminance by external ambient light, and an illuminance input section capable of manually inputting data indicating the illuminance. It is characterized in that the sensor and the illuminance input section can be switched.

As described above, since the illuminance can be automatically detected by providing the sensor, it is possible to perform the optimum display corresponding to the change of the illuminance in real time.
Further, when the illuminance is set manually, it is possible to perform display that accurately reflects the user's intention. Further, since these can be freely switched, it is possible to perform highly convenient gradation setting.

Further, in the image display device of the present invention, the correction curve is converted so that the output data has higher lightness than the input data in the high lightness portion, while the output data has higher lightness in the low lightness portion. Is also characterized in that the output data is converted so that the brightness becomes lower.

As described above, the present inventor has conducted an experiment that when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light, the contrast increases as the illuminance increases. Found by. That is, when the illuminance is high, the contrast is also high, so that it is not necessary to correct the contrast, but when the illuminance is low, the contrast is low, and in this case, it is necessary to correct the contrast. When correcting the contrast, as described above, the output data is converted so that the lightness is higher than the input data in the high lightness portion, while the output data is higher in the lightness portion than the input data. By converting the lightness to be low, it is possible to increase the contrast in the intermediate portion between white and black. That is, when the illuminance is low, the contrast of the original image data is low, but by performing the above correction, among the data existing in the intermediate portion between white and black, white is emphasized in the data close to white and black. Black is emphasized for data close to. As a result, even if the illuminance is low, the contrast is strong, and high-precision and high-quality display can be performed.

Further, the image display method of the present invention is an image display method for performing semi-transmissive reflection display by rear surface transmitted light and external ambient light, the step of detecting illuminance by the external ambient light, and the rear surface transmitted light. And a step of setting a correction curve for correcting the contrast of the image data based on the detected illuminance, which is determined from the relationship between the illuminance and the contrast when components other than the transmitted component and the reflected component of the external environment light are present. And a step of converting the image data based on the set correction curve,
Performing a semi-transmissive reflection display of the converted image data.

With this configuration, it is possible to set the correction curve based on the relationship between the illuminance and the contrast in the case where there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light according to the illuminance. Therefore, it is possible to perform the display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

Further, in the image display method of the present invention, the correction curve has a higher contrast as the illuminance becomes higher when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. It is characterized by being determined based on the relationship between the illuminance and the contrast.

The inventor of the present invention has found by experiments that when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environmental light, the contrast increases as the illuminance increases. By determining the correction curve based on this relationship, it is possible to perform display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

In the image display method of the present invention, the correction curve is set when the detected illuminance is lower than the reference value, and the contrast is not corrected when the detected illuminance is higher than the reference value. It is characterized by setting a curve.

The present inventor has found through experiments that the contrast increases as the illuminance increases when there are components other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. That is, when the illuminance is high, the contrast is also high, so that it is not particularly necessary to correct the contrast. Therefore, when the illuminance is higher than the reference value, a correction curve that does not correct the contrast is set. As a result, natural gradation expression can be performed. On the other hand, when the illuminance is lower than the reference value, the contrast also becomes low. In this case, therefore, a correction curve for correcting the contrast is set. This makes it possible to perform high-contrast display even when the illuminance is low.

Further, in the image display method of the present invention, the ratio between the correction curve and the correction curve in which the contrast is not corrected is set according to the detected illuminance, and the correction curve and the contrast are corrected based on the ratio. The feature is that a correction curve that is combined with a correction curve that does not perform is set.

Since the gradation characteristics continuously change with changes in illuminance, as described above, the correction curve for contrast correction and the correction curve for no contrast correction are set based on the ratio according to the illuminance. Set the combined correction curve. This makes it possible to avoid a sudden change in the gradation setting with a certain illuminance as a boundary. Further, even when the illuminance changes frequently, it is possible to perform an appropriate display without making the user feel uncomfortable.

Further, in the image display method of the present invention, the correction curve is converted so that the output data has a higher lightness than the input data in the high lightness portion, while the output curve has a higher lightness than the input data in the low lightness portion. Is also characterized in that the output data is converted so that the brightness becomes lower.

As described above, the present inventor has conducted an experiment that the contrast increases as the illuminance increases when there are components other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light. Found by. That is, when the illuminance is high, the contrast is also high, so that it is not necessary to correct the contrast, but when the illuminance is low, the contrast is low, and in this case, it is necessary to correct the contrast. When correcting the contrast, as described above, the output data is converted so that the lightness is higher than the input data in the high lightness portion, while the output data is higher in the lightness portion than the input data. By converting the lightness to be low, it is possible to increase the contrast in the intermediate portion between white and black. That is, when the illuminance is low, the contrast of the original image data is low, but by performing the above correction, among the data existing in the intermediate portion between white and black, white is emphasized in the data close to white and black. Black is emphasized for data close to. As a result, even if the illuminance is low, the contrast is strong, and high-precision and high-quality display can be performed.

Further, the image display program of the present invention is an image display program for performing semi-transmissive reflection display by rear surface transmitted light and external ambient light, and a process of detecting illuminance by the external ambient light and the rear surface transmitted light. Process of setting a correction curve that is determined from the relationship between the illuminance and the contrast when there is a component other than the transmission component of the external ambient light and the reflection component of the external environment light, and that corrects the contrast of the image data based on the detected illuminance And a process of converting the image data based on the set correction curve,
It is characterized in that the computer is caused to execute a process of performing semi-transmissive reflection display of the converted image data.

With this configuration, it is possible to set the correction curve based on the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light according to the illuminance. Therefore, it is possible to perform the display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

Further, in the image display program of the present invention, the correction curve has a higher contrast as the illuminance becomes higher when there are components other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. It is characterized by being determined based on the relationship between the illuminance and the contrast.

The inventor of the present invention has found through experiments that when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environmental light, the contrast increases as the illuminance increases. By determining the correction curve based on this relationship, it is possible to perform display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

The image display program of the present invention sets the correction curve when the detected illuminance is lower than the reference value, and does not correct the contrast when the detected illuminance is higher than the reference value. It is characterized by setting a curve.

The present inventor has found through experiments that the contrast increases as the illuminance increases when there are components other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. That is, when the illuminance is high, the contrast is also high, so that it is not particularly necessary to correct the contrast. Therefore, when the illuminance is higher than the reference value, a correction curve that does not correct the contrast is set. As a result, natural gradation expression can be performed. On the other hand, when the illuminance is lower than the reference value, the contrast also becomes low. In this case, therefore, a correction curve for correcting the contrast is set. This makes it possible to perform high-contrast display even when the illuminance is low.

Further, the image display program of the present invention determines the ratio between the correction curve and the correction curve in which the contrast is not corrected according to the detected illuminance, and corrects the correction curve and the contrast based on the ratio. The feature is that a correction curve that is combined with a correction curve that does not perform is set.

Since the gradation characteristic changes continuously with changes in illuminance, as described above, the correction curve for contrast correction and the correction curve for no contrast correction are set based on the ratio according to the illuminance. Set the combined correction curve. This makes it possible to avoid a sudden change in the gradation setting with a certain illuminance as a boundary. Further, even when the illuminance changes frequently, it is possible to perform an appropriate display without making the user feel uncomfortable.

Further, in the image display program of the present invention, the correction curve is converted so that the illuminance of the output data becomes higher than that of the input data in a portion where the illuminance is high.
The feature is that the conversion is performed so that the illuminance of the output data is lower than that of the input data in the portion where the illuminance is low.

As described above, the present inventor has conducted an experiment to find that when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light, the contrast increases as the illuminance increases. Found by. That is, when the illuminance is high, the contrast is also high, so that it is not necessary to correct the contrast, but when the illuminance is low, the contrast is low, and in this case, it is necessary to correct the contrast. When correcting the contrast, as described above, the output data is converted so that the lightness is higher than the input data in the high lightness portion, while the output data is higher in the lightness portion than the input data. By converting the lightness to be low, it is possible to increase the contrast in the intermediate portion between white and black. That is, when the illuminance is low, the contrast of the original image data is low, but by performing the above correction, among the data existing in the intermediate portion between white and black, white is emphasized in the data close to white and black. Black is emphasized for data close to. As a result, even if the illuminance is low, the contrast is strong, and high-precision and high-quality display can be performed.

Further, the computer-readable recording medium of the present invention is characterized in that the image display program described in any one of the above is recorded.

By causing a computer to execute the image program recorded on this recording medium, the image program based on the relationship between the illuminance and the contrast in the case where there are components other than the transmitted component of the rear transmitted light and the reflected component of the external ambient light is used. The correction curve can be set according to the illuminance. As a result, it is possible to perform a display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

[0051]

BEST MODE FOR CARRYING OUT THE INVENTION The present inventor has conducted an experiment to find that when there is a component other than a transmitted component of rear-side transmitted light and a reflected component of the external ambient light, the contrast increases as the illuminance increases. Found by. In the present embodiment, a correction curve is determined based on this relationship, and the contrast is corrected according to the illuminance.

FIG. 1 is a block diagram showing a schematic configuration of the image display device according to the present embodiment. In this image display device 100, image data is input from the image data input unit 1, and the illuminance detection unit 2 as a sensor automatically detects the illuminance due to external ambient light. The manual illuminance setting unit 3 is used to manually set the illuminance by the user. The illuminance detection unit 2 and the manual illuminance setting unit 3 function by being selectively switched by a changeover switch 4a included in the illuminance input unit 4.

As described above, since the illuminance detecting section 2 can automatically detect the illuminance, it is possible to perform the optimum display corresponding to the change in the illuminance in real time. Also,
When the illuminance is manually set in the manual illuminance setting unit 3, it is possible to perform a display that accurately reflects the user's intention. Further, these can be freely switched by the changeover switch 4a provided in the illuminance input section 4, so that it is possible to perform gradation setting with high convenience.

The gradation characteristic setting unit 5 compares the illuminance input from the illuminance input unit 4 with a reference value, and switches whether to correct the contrast or not. The operation of the gradation characteristic setting unit 5 is performed based on the flowchart shown in FIG. That is, when the illuminance signal is input from the illuminance signal input unit 4 (step S1), it is determined whether the illuminance is a predetermined value (reference value) or more (step S2).
If the result of this determination is that the illuminance is greater than or equal to the predetermined value, the gradation characteristic setting unit 5 sets gradation using a correction curve that does not correct contrast (step S3), and ends. On the other hand, if the illuminance is not equal to or more than the predetermined value in step S2, the gradation is set using the correction curve for correcting the contrast (step S4), and the process ends. The predetermined value (reference value) described above may be, for example, an illuminance of 1000 [lx]. As shown in the diagram on the right end of FIG. 8, the contrast increases as the illuminance increases, and the rate of increase decreases when the illuminance exceeds 1000 [lx]. When the illuminance is more than 1000 [lx], the contrast is sufficient and it is not necessary to correct the contrast. On the other hand, the illuminance is 1000
When the value is lower than [lx], the contrast sharply decreases, so that it is necessary to correct the contrast. For this reason,
In the present embodiment, the reference value is when the illuminance is 1000 [lx]. However, the present invention is not limited to this value.

The correction curve for correcting the contrast has the characteristics shown on the left side of FIG. 3, and the correction curve for not correcting the contrast has the characteristics shown on the right side of FIG. As shown on the left side of FIG. 3, the correction curve for correcting the contrast converts the output data so that the output data has a higher brightness than the input data in a high brightness portion, and the input data in a low brightness portion. The output data is converted so that it has lower brightness than the data.

As described above, the present inventor has conducted an experiment that the contrast increases as the illuminance increases when the components other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light exist. Found by. That is, when the illuminance is high, the contrast is also high, so that it is not necessary to correct the contrast, but when the illuminance is low, the contrast is low, and in this case, it is necessary to correct the contrast. When correcting the contrast, as described above, the output data is converted so that the lightness is higher than the input data in the high lightness portion, while the output data is higher in the lightness portion than the input data. By converting the lightness to be low, it is possible to increase the contrast in the intermediate portion between white and black. That is, when the illuminance is low, the contrast of the original image data is low, but by performing the above correction, among the data existing in the intermediate portion between white and black, white is emphasized in the data close to white and black. Black is emphasized for data close to. As a result, even if the illuminance is low, the contrast is strong, and high-precision and high-quality display can be performed.

By comparing the curve with contrast correction shown on the left side of FIG. 3 with the curve without contrast correction shown on the right side, the mechanism of contrast enhancement can be well understood. Comparing the left side and the right side of FIG. 3, the brightness of the data 192 corresponding to the intermediate white is larger on the left side than on the right side. The brightness of the data 64 corresponding to the intermediate black is smaller on the left side than on the right side. Therefore, when a curve with contrast correction on the left side is used, white is emphasized for data close to white and black is emphasized for data close to black, as compared with the case where a curve on the right side is used.

On the other hand, the correction curve shown on the right side of FIG. 3 is a normal gamma curve (y = x ^γ ) and, for example, the gamma value is set within the range of γ = 1.5 to 1.8. .

As described above, when the detected illuminance is lower than the reference value, the correction curve for correcting the contrast is set, and when the detected illuminance is higher than the reference value, the correction curve for not correcting the contrast is set. . Thereby, when the illuminance is higher than the reference value, it is possible to perform natural gradation expression. On the other hand, when the illuminance is lower than the reference value, a correction curve for correcting the contrast is set, so that it is possible to perform display with high contrast even when the illuminance is low.

Further, in FIG. 1, the data conversion unit 6 is
Based on the gradation characteristic set in the gradation characteristic setting unit 5, for example, data conversion is performed on the input image data using a LUT (Look-up-table) to generate display data. The generated display data is
It is displayed on the image data display unit 7.

Next, another operation example of the gradation characteristic setting unit 5 will be described with reference to FIGS. 4 and 5. Here, the ratio of the correction curve that corrects the contrast and the correction curve that does not correct the contrast is determined according to the illuminance input from the illuminance input unit 4. Then, based on this ratio, a correction curve in which a correction curve for correcting the contrast and a correction curve for not correcting the contrast are combined is set.

In FIG. 4, when an illuminance signal is input from the illuminance input unit 4 (step T1), the gradation characteristic setting unit 5
Calculates the gradation setting for correcting the contrast (step T2). That is, if the gradation setting for correcting the contrast is C _ON , the gradation setting for not correcting the contrast is C _OFF , and the weight (ratio) is w, the calculation of the gradation setting for correcting the contrast is performed. , Can be performed by the following formula.

[0063]

[Equation 3]

As a result, as shown in FIG. 5, the weight (ratio) w can be continuously changed based on the illuminance I. Since the gradation characteristics continuously change due to changes in illuminance, in this operation example, the correction curve for correcting the contrast and the correction curve for not correcting the contrast are weighted (ratio ) Is set based on the correction curve. This makes it possible to avoid a sudden change in the gradation setting with a certain illuminance as a boundary. Also, even when the illuminance changes frequently,
It is possible for the user to perform an appropriate display without feeling discomfort.

In FIG. 5, the weight (ratio) w decreases linearly between the preset thresholds I _ON and I _OFF of the illuminance, but the change of w changes to that of FIG. Not exclusively. Specifically, w needs only to work so as to reduce the ratio with contrast correction by increasing the illuminance, and therefore it only has to monotonically decrease with the increase in the illuminance I. For this reason, if the change characteristic of w is set as another smooth change characteristic than that shown in FIG. 5, it is possible to switch between the presence and absence of contrast correction more continuously and without making the user feel uncomfortable. .

Next, the experimental data of the influence of the scattering component on the transmission-oriented panel will be described.
The transflective liquid crystal panel includes a transmission-oriented panel and a reflection-oriented panel. The transmissive priority panel is a panel in which the transmissive component due to the backlight light is emphasized, and the reflective importance panel is a panel in which the reflective component due to the external environment light is emphasized. As described above, a liquid crystal panel (LC
In D), the transmission component due to the back-transmitted light, the reflection component due to the external environment light, and the components other than these contribute to the generation of light, and in white and black, the light transmittance and the diffuse reflection coefficient. , And the scattered components are different. The characteristics of the transmission-oriented panel will be described below.

FIG. 9 shows, from the left side, white display brightness, black display brightness, and contrast when no scattering component is present. Further, FIG. 10 shows, from the left side, white display brightness, black display brightness, and contrast when a scattered component is present. The parameters are as follows: In addition,
Since the emphasis is on transmission, the parameter contributing to transmission is increased while the parameter contributing to reflection is decreased.
In addition, here, it is assumed that the scattering component does not particularly change even if transmission is emphasized. T _ON : 0.02, R _ON : 2.55, L: 1500, T _OFF : 0.0016, R _OFF : 0.22

The relationship between D _ON (I) and D _OFF (I) due to the scattering component and the illuminance is the same as that shown in Table 1.

Comparing FIG. 9 and FIG. 10, with respect to the white display brightness and the black display brightness, the display brightness increases as the illuminance increases, regardless of the presence or absence of the scattered component.

However, regarding the contrast shown on the right side of both figures, when the illuminance is high when the scattering component is not present, the contrast sharply decreases, but when the scattering component is present, the illuminance is high. Then the contrast is correspondingly higher. In particular, in the case of a transmission-oriented panel, the illuminance at which the contrast is saturated is large. Therefore, in the case of a transmission-oriented panel, the reference value of the illuminance at the time of determining whether to perform contrast correction has a large value.

This can be explained as follows. First, it is considered that the contrast of the transflective LCD panel is saturated in a portion where the illuminance is high when the reflection component due to the external environment light becomes more dominant than the transmission component due to the backlight light. Here, in the transmissive priority panel, since the transmissive component due to the backlight light is emphasized, conversely, the ratio of the reflective component due to the external environmental light is small. Therefore, in order for the reflection component to be dominant over the transmission component, a larger illuminance than that of the reflection-oriented panel is required. From this, as shown in FIG. 10, it can be considered that the illuminance at which the contrast is saturated shifts to the larger side in the transmission-oriented panel, and the illuminance threshold for determining whether to perform the contrast correction is set to a large value.

The gradation characteristic setting unit 5 is provided in a server capable of transmitting and receiving data on the communication network, and an illuminance signal is transmitted from the communication terminal device to the server via the communication network and set by the above-mentioned method on the server side. It is also possible to send the correction curve to the communication terminal device via the communication network.

The characteristic operation of the image display device as described above is performed by executing the image display program. This image processing program is an image display program for performing semi-transmissive reflection display by rear surface transmitted light and external environmental light, and processing for detecting illuminance by the external environmental light, transmission component of the rear surface transmitted light, and the external environment. A process of setting a correction curve that is determined from the relationship between the illuminance and the contrast when a component other than the reflection component of light is present, and that corrects the contrast of the image data based on the detected illuminance; and the set correction. It is characterized by causing a computer to execute a process of converting the image data based on a curve and a process of displaying the converted image data in semi-transmissive reflection.

With this configuration, it is possible to set a correction curve based on the relationship between the illuminance and the contrast in the case where there are components other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light, according to the illuminance. Therefore, it is possible to perform the display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

Further, the image processing program as described above can be distributed independently by being recorded in a recording medium such as a CD-ROM or a DVD disk or placed in a state of being transmittable on a WEB page. Is possible.

[0076]

As described above, the image display device of the present invention is an image display device for performing semi-transmissive reflection display by rear transmitted light and external environmental light, and an input section for inputting image data, and An illuminance detection unit that detects the illuminance due to external ambient light, is determined from the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light, and the detected illuminance. A correction curve setting unit for setting a correction curve for correcting the contrast of the image data based on the above, a data conversion unit for converting the image data into display data based on the set correction curve, and the converted display. And a display panel for performing semi-transmissive reflection display of data.

With this configuration, it is possible to set the correction curve based on the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environment light according to the illuminance. Therefore, it is possible to perform the display suitable for the usage environment. Further, since the gradation characteristic can be set in consideration of the contrast characteristic of the display device, it is possible to perform display with higher accuracy and higher quality.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of an image display device according to an embodiment.

FIG. 2 is a flowchart showing an operation of a gradation characteristic setting unit.

FIG. 3 is a diagram showing a correction curve.

FIG. 4 is a flowchart showing another operation of the gradation characteristic setting unit.

FIG. 5 is a diagram showing a state in which the weight is continuously changed depending on the illuminance.

FIG. 6 is a diagram showing an example of a transflective LCD panel.

FIG. 7 is a diagram showing white display brightness, black display brightness, and contrast when no scattering component exists.

FIG. 8 is a diagram showing white display brightness, black display brightness, and contrast when a scattering component is present.

FIG. 9 is a diagram showing white display brightness, black display brightness, and contrast when a scattering component does not exist in the transmission-oriented panel.

FIG. 10 is a diagram showing white display brightness, black display brightness, and contrast when a scattering component is present in a transmission-oriented panel.

[Explanation of symbols]

1 Image data input section 2 Illuminance detector 3 Manual illuminance setting section 4 Illuminance input section 5 gradation characteristic setting section 6 Data converter 7 Image data display

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Claims (17)

[Claims] 1. An image display device for performing semi-transmissive reflection display by rear-surface transmitted light and external ambient light, comprising: an input unit for inputting image data; an illuminance detection unit for detecting illuminance by the external ambient light; A correction curve for correcting the contrast of the image data based on the detected illuminance is determined based on the relationship between the illuminance and the contrast when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external ambient light. A correction curve setting unit for setting, a data conversion unit for converting the image data based on the set correction curve, and a display panel for performing semi-transmissive reflection display of the converted image data, Image display device. 2. The correction curve is based on the relationship between the illuminance and the contrast in which the contrast increases as the illuminance increases when there is a component other than the transmitted component of the rear surface transmitted light and the reflected component of the external environmental light. The image display device according to claim 1, wherein the image display device is defined as follows. 3. The correction curve setting unit sets the correction curve when the detected illuminance is lower than a reference value, and does not correct the contrast when the detected illuminance is higher than the reference value. The image display device according to claim 1, wherein 4. The correction curve setting unit determines a ratio between the correction curve and a correction curve in which the contrast is not corrected according to the detected illuminance, and corrects the correction curve and the contrast based on the ratio. The image display device according to claim 1, wherein a correction curve is set by combining the correction curve with a correction curve that does not exist. 5. The illuminance detection unit includes a sensor that automatically detects illuminance due to external ambient light, and an illuminance input unit that can manually input data indicating the illuminance, and the sensor and the illuminance input unit. The image display device according to claim 1, wherein the image display device is switchable. 6. The correction curve is converted so that the output data has a higher lightness than the input data in a high lightness portion, while the output data has a lighter lightness in the low lightness portion than the input data. The image display device according to claim 1, wherein conversion is performed so that the image display device becomes lower. 7. An image display method for performing semi-transmissive reflection display by back-transmitted light and external ambient light, comprising: detecting illuminance due to the external ambient light; And a step of setting a correction curve for correcting the contrast of the image data based on the detected illuminance, which is determined from the relationship between the illuminance and the contrast when a component other than the reflection component is present, and the set correction curve An image display method comprising: a step of converting the image data based on the above; and a step of performing semi-transmissive reflection display of the converted image data. 8. The correction curve is based on the relationship between the illuminance and the contrast in which the contrast increases as the illuminance increases when a component other than the transmitted component of the back transmitted light and the reflected component of the external ambient light exists. The image display method according to claim 7, wherein the image display method is defined as follows. 9. The correction curve is set when the detected illuminance is lower than a reference value, and the correction curve which does not correct the contrast is set when the detected illuminance is higher than the reference value. The image display method according to claim 7. 10. A ratio between the correction curve and a correction curve without contrast correction is determined according to the detected illuminance, and the correction curve and the correction curve without contrast correction are combined based on the ratio. The image display method according to claim 7, wherein a correction curve is set. 11. The correction curve is converted so that the output data has a higher lightness than the input data in a high lightness portion, while the output data has a lighter lightness in the low lightness portion than the input data. The image display method according to claim 7, wherein conversion is performed so as to lower the value. 12. An image display program for performing semi-transmissive reflection display by back-transmitted light and external ambient light, the process comprising: detecting the illuminance by the external ambient light; Processing for setting a correction curve for correcting the contrast of the image data on the basis of the detected illuminance, which is determined from the relationship between the illuminance and the contrast when a component other than the reflection component is present, and the set correction curve An image display program for causing a computer to execute a process of converting the image data based on the above, and a process of performing a semi-transmissive reflection display of the converted image data. 13. The correction curve is based on the relationship between the illuminance and the contrast in which the contrast increases as the illuminance increases when a component other than the transmitted component of the back transmitted light and the reflected component of the external ambient light exists. 13. The image display program according to claim 12, wherein the image display program is defined by: 14. The correction curve is set when the detected illuminance is lower than a reference value, and the correction curve which does not correct the contrast is set when the detected illuminance is higher than the reference value. The image display program according to claim 12. 15. A ratio between the correction curve and a correction curve without contrast correction is determined according to the detected illuminance, and the correction curve and the correction curve without contrast correction are combined based on the ratio. The image display program according to claim 12, wherein a correction curve is set. 16. The correction curve is converted so that the output data has a higher lightness than the input data in a high lightness portion, while the output data has a lighter lightness in the low lightness portion than the input data. 13. The image display program according to claim 12, wherein conversion is performed so that the image display program becomes lower. 17. A computer-readable recording medium on which the image display program according to any one of claims 12 to 16 is recorded.