Color liquid crystal panel having opening in color filter varied according to color, method for manufacturing the same, and color liquid crystal display device employing the same Number:7,142,269 from the United States Patent and Trademark Office (PTO) owispatent

Title: Color liquid crystal panel having opening in color filter varied according to color, method for manufacturing the same, and color liquid crystal display device employing the same

Abstract: Within a reflective display section R, a part of a light that reaches a reflective electrode through a color filter exits to the outside through slits and a part of a light that reaches the reflective electrode through the slits exits to the outside through the color filter. In addition, a light reaching the reflective electrode through the color filter and exiting to the outside through the color filter, and a light having no opportunity to pass through the slits also can be observed. Therefore, a mean film thickness of color filter through which all lights pass during the time in which they travel the associated distance after they are inputted to the inside until they are outputted to the outside becomes nearly equal to that could be observed in the transmissive section T.

Patent Number: 7,142,269 Issued on 11/28/2006 to Ikeno,   et al.

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Inventors:	Ikeno; Hidenori (Tokyo, JP), Fujimaki; Eriko (Tokyo, JP)
Assignee:	NEC Corporation (Tokyo, JP) NEC LCD Technologies, Ltd. (Kanagawa, JP)
Appl. No.:	10/983,195
Filed:	November 8, 2004

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Related U.S. Patent Documents

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	Application Number	Filing Date	Patent Number	Issue Date
	10122342	Apr., 2002	6897922

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Foreign Application Priority Data

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Apr 16, 2001 [JP]			2001-117041

Current U.S. Class:	349/109 ; 349/106; 349/113; 349/114
Current International Class:	G02F 1/1335 (20060101)
Field of Search:	349/106,109,113,114

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References Cited [Referenced By]

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U.S. Patent Documents

	5642176		June 1997		Abukawa et al.
	6124909		September 2000		Miyashita et al.
	6215538		April 2001		Narutaki et al.
	6380995		April 2002		Kim
	6501521		December 2002		Matsushita et al.
	2001/0004276		June 2001		Urabe et al.

Foreign Patent Documents

	10-154817		Jun., 1998		JP
	2000-111902		Apr., 2000		JP
	2000-162644		Jun., 2000		JP
	99/28782		Jun., 1999		WO

Primary Examiner: Schechter; Andrew
Assistant Examiner: Caley; Michael H.
Attorney, Agent or Firm: Young & Thompson

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Parent Case Text

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CROSS REFERENCE TO RELATED APPLICATIONS

This application is a division of application Ser. No. 10/122,342, filed on Apr. 16, 2002 now U.S. Pat. No. 6,897,922, the entire contents of which are hereby incorporated by reference.

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Claims

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What is claimed is:

1. A method for manufacturing a color liquid crystal panel, said color liquid crystal panel having plural pixels, each having a thin film transistor therein, a reflective electrode connected to said thin film transistor, and a transparent electrode, said color liquid crystal panel being constructed such that a display surface of said color liquid crystal panel allows a light emitted from a backlight to exit from said display surface through said transparent electrode and another light inputted to said display surface to exit from said display surface after being reflected by said reflective electrode, said method for manufacturing said color liquid crystal panel comprising the steps of: preparing a photomask in such a manner that at least one opening is formed in said photomask so as to vary an area of said at least one opening depending on a color to be displayed; and forming a pattern in a raw material film constituting said color filter by using said photomask to make said color filter have at least one opening varying depending on a color to be displayed in a part thereof facing said reflective electrode, the at least one opening in said color filter having an area that is no more than 40% of an area of said reflective electrode.

2. The method for manufacturing a color liquid crystal panel according to claim 1, further having a step of forming a transparent film covering all color filters formed corresponding to colors to be displayed and a step of flattening said transparent film after a step of forming said color filter.

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Description

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BACKGROUND OF THE INVENTION

1. Technical Field of the Invention

The present invention relates to a color liquid crystal panel suitably used as a display of a portable telephone, a method for manufacturing the same, and further a color liquid crystal display device employing the same, more particularly, to a color liquid crystal panel having an enhanced capability of displaying high quality images, a method for manufacturing the same, and further a color liquid crystal display device employing the same.

2. Description of the Related Art

It is conventionally known that a semi-transmissive liquid crystal display device consisting of a plurality of pixels, each having a transmissive display section and a reflective display section therein, has been developed as a liquid crystal display device equipped with both features of a transmissive liquid crystal display device and a reflective liquid crystal display device. In such a semi-transmissive liquid crystal display device, a color filter for a transmissive display section and a color filter for a reflective display section are provided corresponding to each color to be displayed and therefore, totally six kinds of color filters are to be provided corresponding to each color. Accordingly, in order to manufacture a color liquid crystal display device having the above-described construction of color filter, it is necessary that six kinds of photoresist films are prepared corresponding to those color filters and then, six photolithography steps are carried out. Consequently, there has been found a drawback in that the semi-transmissive liquid crystal display device manufactured in accordance with the above-described method results in a low yield and high manufacturing cost thereof.

In consideration of the above-stated drawback, the following semi-transmissive liquid crystal display device has recently been disclosed in publications such as Japanese Patent Application Laid-open No. 2000-111902. That is, a semi-transmissive liquid crystal display device is constructed such that only one kind of color filter is formed corresponding to each color and a region in which no color filter exists is formed within a reflective display section.

FIG. 1 is a plan view illustrating a layout of a TFT substrate included in a conventional semi-transmissive liquid crystal display device disclosed in Japanese Patent Application Laid-open No. 2000-111902 and FIG. 2 is a cross sectional view of a liquid crystal panel employed in the conventional semi-transmissive liquid crystal display device, taken along the line A--A of FIG. 1.

In the conventional semi-transmissive liquid crystal display device disclosed in the publication, a red color pixel 101R, a green color pixel 101G and a blue color pixel 101B are disposed in this order in a direction in which a scanning signal line extends. In each pixel, a thin film transistor (TFT) 102 is formed. The thin film transistor 102 consists of a gate electrode 103a projecting from a gate line 103 as the scanning signal line and a drain electrode 104a projecting from a drain line 104 that extends in a direction perpendicular to the gate line. The gate line 103 and the gate electrode 103a are formed on a transparent substrate 100a and further, an insulation film 105 is formed on the transparent substrate 100a covering the gate line 103 and the gate electrode 103a. The drain line 104 is formed on the insulation film 105. An amorphous silicon layer 106 is formed on the insulation film 105 to face the gate electrode 103a and the drain electrode 104a is formed extending on the amorphous silicon layer 106. Furthermore, a source electrode 107 is formed extending from the amorphous silicon layer 106 in a direction apart from the drain electrode 104a while a part of the source electrode is at least positioned on and inside the amorphous silicon layer.

Within a reflective display section of each pixel, projecting portions 108 are formed on the insulation film 105 and within a transmissive display section, a transparent electrode 109 is formed on the insulation film 105. Note that the reflective display section is formed to surround the transmissive display section. Furthermore, within a region excluding the transmissive display section in each pixel, an insulation film 110 covering the projecting portions 108, the thin film transistor 102 and the like is formed and further, a contact hole 111 is formed in the insulation film 110 so as to reach the surface of the source electrode 107. A reflective electrode 112 is formed within the contact hole 111 and on the insulation film 105. The reflective electrode 112 has a convex-concave surface reflecting the profile of the projecting portions 108. The reflective electrode 112 is connected also to the transparent electrode 109. Furthermore, a retardation film 113 and a polarizer 114 are formed on the transparent substrate 100a on a side thereof defined as the surface on which elements such as the thin film transistor 102 are not formed. The elements constructed as described above constitute a TFT substrate.

Additionally, another transparent substrate 100b is disposed in parallel with the transparent substrate 100a on a side thereof defined as the surface on which the thin film transistor 102 is formed. A color filter (CF) 121 and an opposing electrode 122 are formed on a surface of the transparent substrate 100b on a side thereof facing the transparent substrate 100a. As shown in FIG. 1, the color filter 121 is formed extending in parallel with the drain line 104 and further, when viewing a pixel in a direction perpendicular to a surface of the associated transparent substrate, the transparent electrode 109 is being formed inside with respect to both end lines of the color filter 121 whereas the reflective electrode 112 is being formed to have a width extending beyond the both lines thereof. Furthermore, a retardation film 123 and a polarizer 124 are formed on the transparent substrate 100b on a side thereof defined as the surface on which elements such as the color filter 121 are not formed. The elements constructed as described above constitute a CF substrate.

In addition to the above-described construction of liquid crystal panel, a liquid crystal 130 is interposed between the TFT substrate and the CF substrate to constitute the liquid crystal panel.

The conventional color liquid crystal display device constructed as described above has one kind of color filter therein corresponding to each color and therefore, can be manufactured through a reduced number of process steps, thereby improving a yield thereof.

Furthermore, as the color filter 121 of the CF substrate employed in the above-described color liquid crystal display device has a region therein, facing the reflective electrode 112, in which the color filter 121 is not formed, the color liquid crystal display device can offer a display brightness greater than that could be achieved in a color liquid crystal display device developed before the emergence of color liquid crystal display device employing such construction of the color filter 121.

Moreover, the conventional reflective liquid crystal display device has projecting portions formed under the reflective electrode and extending in all directions. The projecting portions are designed to have a pattern optimal in terms of paths of an incident light and a reflected light. FIG. 3 illustrates a layout of projecting portions employed in the conventional liquid crystal display device. In a reflective liquid crystal display device, the projecting portions 108 are formed without especially taking into account the effect of boundaries between pixels. In addition, a liquid crystal display device having a transmissive display section and a reflective display section therein includes such projecting portions only within the reflective display section.

However, it has been found a problem in that the conventional semi-transmissive liquid crystal display device employing one kind of color filter corresponding to each pixel in order to, for example, reduce the number of process steps to be carried out to manufacture the device has an image quality inferior to that of a device employing two kinds of color filters therein, which has been developed before the emergence of the device employing one kind of color filter.

Furthermore, it has also been found another problem in that both a reflective liquid crystal display device and a semi-transmissive liquid crystal display device have displayed images appearing pale yellow in color thereon.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a color liquid crystal panel capable of improving quality of images to be displayed in a semi-transmissive liquid crystal display device, a method for manufacturing the same, and further a color liquid crystal display device employing the same.

A color liquid crystal panel according to the first aspect of the present invention comprises a thin film transistor, a reflective electrode connected to the thin film transistor and a transparent electrode in each pixel thereof. Furthermore, the color liquid crystal panel is constructed such that a display surface of the color liquid crystal panel allows a light emitted from a backlight to exit from the display surface through the transparent electrode and another light inputted to the display surface to exit from the display surface after being reflected by the reflective electrode. Additionally, the color liquid crystal panel is constructed such that the color liquid crystal panel has a color filter therein so that at least one opening varying an area thereof depending on a color to be displayed is formed in the color filter in a part thereof facing the reflective electrode, and color reproduction ranges of the light exiting from the display surface through the transparent electrode and the another light exiting from the display surface after being reflected by the reflective electrode substantially coincide with each other.

It should be noted that the color liquid crystal panel of the first aspect of the present invention is further and preferably constructed as follows. That is, a red color filter, a green color filter and a blue color filter are respectively formed as the color filter and a ratio of an area of the at least one opening formed in the color filter with respect to an area of the color filter becomes maximum in the event the green color filter is selected as the color filter to calculate the ratio. The color liquid crystal panel is more preferably constructed as follows. That is, in the case where a white-colored light source is employed as the backlight, the ratio of an area of the at least one opening formed in the green color filter with respect to an area of the green color filter is made two to four times the ratio of an area of the at least one opening formed in one of the red color filter and the blue color filter with respect to an area of associated one of the red color filter and the blue color filter.

Additionally, the color liquid crystal panel of the first aspect of the present invention described so far is preferably constructed as follows. That is, the ratio of an area of the at least one opening formed in the color filter with respect to an area of the color filter in the color filter in a part thereof facing the reflective electrode is set at a value of not greater than 50% and further, the at least one opening is formed shaped like a slit and a width of the slit is set at a value of 1 .mu.m to 10 .mu.m.

A color liquid crystal panel constructed in accordance with the second aspect of the present invention has a thin film transistor, a reflective electrode connected to the thin film transistor and a transparent electrode in each pixel thereof. Furthermore, the color liquid crystal panel is constructed such that a display surface of the color liquid crystal panel allows a light emitted from a backlight to exit from the display surface through the transparent electrode and another light inputted to the display surface to exit from the display surface after being reflected by the reflective electrode. Additionally, the color liquid crystal panel comprises a color filter and a transparent film formed between the color filter and a transparent substrate while varying a volume thereof depending on a color to be displayed, in which color reproduction ranges of the light exiting from the display surface through the transparent electrode and the another light exiting from the display surface after being reflected by the reflective electrode substantially coincide with each other.

A color liquid crystal panel constructed in accordance with the third aspect of the present invention comprises a transparent substrate, a thin film transistor formed in each pixel on the transparent substrate, an insulation film formed on the transparent substrate to have a convex-concave surface within the each pixel, a reflective electrode formed on the insulation film and connected to the thin film transistor in the each pixel, in which the insulation film has projecting portions each extending along a boundary between adjacent pixels and having a width substantially equal to that of projecting portions constituting the convex-concave surface within the each pixel.

To solve the above-described problems, the inventors of the application have energetically and repeatedly carried out experiments and studies, and finally found the following problems included in the conventional technology that is disclosed such as in Japanese Patent Application Laid-open No. 2000-111902. That is, in a transmissive and reflective liquid crystal display device having one kind of color filter formed corresponding to a color to be displayed, respective patterns of openings formed in associated color filters coincide with each other even though human visual sensitivity varies depending on a color to be displayed. Accordingly, this construction of color filter having such opening therein makes the color reproduction ranges of a transmissive display section and a reflective display section within a pixel different from each other, thereby preventing the transmissive and reflective liquid crystal display device from offering the desirable quality of images to be displayed. Taking into account an adverse effect on the quality of images to be displayed, the present invention has been conceived to have the following construction of liquid crystal panel. That is, as described above, an area of openings formed in a color filter within a reflective display section is made to vary depending on a color to be displayed or a transparent film is formed between a color filter and a transparent substrate while varying the volume of the transparent film depending on a color to be displayed. This construction of liquid crystal panel makes the color reproduction ranges of a transmissive display section and a reflective display section coincide with each other corresponding to a color to be displayed, in other words, with respect to individual colors to be displayed, thereby creating color balanced viewable images corresponding to a color to be displayed, in other words, with respect to individual colors to be displayed, and further achieving high quality images.

Furthermore, the inventors found that images appearing pale yellow in color are caused by the difference in gaps between two substrates at positions thereof located within a pixel and between pixels. Normally in a reflective liquid crystal display device, a black matrix is not formed at the boundary between pixels to make a display bright. For this reason, it is believed that the above-described difference in gaps makes a light travel different distances through a liquid crystal to generate phase difference of light, making images appear pale yellow in color. Therefore, the liquid crystal panel of the present invention is constructed such that projecting portions are formed also at the boundary between pixels to reduce the difference in gaps to thereby reduce pale yellow in color and achieve high quality images.

A method for manufacturing a color liquid crystal panel according to the present invention is constructed as follows. First, the color liquid crystal panel has a thin film transistor, a reflective electrode connected to the thin film transistor and a transparent electrode in each pixel thereof, and is further constructed such that a display surface of the color liquid crystal panel allows a light emitted from a backlight to exit from the display surface through the transparent electrode and another light inputted to the display surface to exit from the display surface after being reflected by the reflective electrode. Secondly, the method for manufacturing the above-described color liquid crystal panel comprises the steps of: preparing a photomask in such a manner that at least one opening is formed in the photomask so as to vary an area of the at least one opening depending on a color to be displayed; and forming the pattern in a raw material film constituting the color filter by using the photomask to make the color filter have the at least one opening therein varying depending on a color to be displayed and facing the reflective electrode.

It should be noted that it is preferable for the method for manufacturing a color liquid crystal panel to further have a step of forming a transparent film covering all color filters formed corresponding to colors to be displayed and a step of flattening the transparent film after a step of forming the color filter.

According to the above-described method for manufacturing a color liquid crystal panel, the color liquid crystal panel constructed in accordance with the first aspect of the present invention and capable of displaying high quality images can be fabricated.

Moreover, a color liquid crystal display device of the present invention comprises a liquid crystal panel constructed in accordance with one of the first, second and third aspects of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view illustrating a layout of a TFT substrate included in a conventional semi-transmissive liquid crystal display device disclosed in Japanese Patent Application Laid-open No. 2000-111902;

FIG. 2 is a cross sectional view of a liquid crystal panel employed in the conventional semi-transmissive liquid crystal display device, taken along the line A--A of FIG. 1;

FIG. 3 illustrates a layout of projecting portions employed in the conventional liquid crystal display device;

FIG. 4 is a plan view of a layout of a TFT substrate employed in a liquid crystal panel of the first embodiment constructed in accordance with the present invention;

FIG. 5 is a cross sectional view taken along the line A--A of FIG. 4;

FIG. 6 is a cross sectional view taken along the line B--B of FIG. 4;

FIG. 7 is a cross sectional view taken along the line C--C of FIG. 4;

FIG. 8 is a graphic illustration of a spectrum of a standard light CIE "C";

FIG. 9 is a graphic illustration of a spectrum of a light emitted from a white-colored LED;

FIG. 10 is a CIE chromaticity diagram showing an optimal color reproduction range to be employed in television display and defined by NTSC;

FIG. 11 is a graphic illustration of a spectrum of a light emitted from the first three-wavelength light source;

FIG. 12 is a graphic illustration of a spectrum of a light emitted from the second three-wavelength light source;

FIGS. 13A, 13B and 13C are plan views illustrating patterns of various color filters within associated pixels;

FIG. 14 is a cross sectional view, taken along the line A--A of FIG. 4, of a liquid crystal panel of the second embodiment constructed in accordance with the present invention;

FIG. 15 is a cross sectional view, taken along the line B--B of FIG. 4, of a liquid crystal panel of the second embodiment constructed in accordance with the present invention;

FIG. 16 is a cross sectional view, taken along the line C--C of FIG. 4, of a liquid crystal panel of the second embodiment constructed in accordance with the present invention;

FIG. 17A is a layout diagram indicating projecting portions formed under a reflective electrode in the liquid crystal panel of the third embodiment of the present invention and FIG. 17B is a schematic cross sectional view of the liquid crystal panel;

FIG. 18 is a schematic diagram to explain the relationship between a width of projecting portion and a height thereof that varies depending on the width;

FIGS. 19A and 19B are schematic diagrams showing the method for manufacturing the projecting portions through two exposure steps;

FIGS. 20A and 20B are schematic diagrams showing the method for manufacturing the projecting portions through two exposure steps and illustrate process steps subsequent to the steps of FIGS. 19A and 19B in order;

FIG. 21 is a schematic diagram showing the method for manufacturing the projecting portions through two exposure steps and illustrates a process step subsequent to the steps of FIGS. 20A and 20B;

FIGS. 22A and 22B are schematic diagrams showing the method for manufacturing the projecting portions through one exposure step;

FIGS. 23A and 23B are schematic diagrams showing the method for manufacturing the projecting portions through one exposure step and illustrate process steps subsequent to the steps of FIGS. 22A and 22B in order;

FIG. 24 is a block diagram illustrating the configuration of a portable information terminal constructed in accordance with the embodiment of the present invention; and

FIG. 25 is a block diagram illustrating the configuration of a portable telephone constructed in accordance with the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

A liquid crystal panel constructed in accordance with embodiments of the present invention, a method for manufacturing the same and a liquid crystal display device employing the same will be described in detail below with reference to the attached drawings. FIG. 4 is a plan view of a layout of a TFT substrate employed in a liquid crystal panel constructed in accordance with the first embodiment of the present invention. FIG. 5 is a cross sectional view taken along the line A--A of FIG. 4, FIG. 6 is a cross sectional view taken along the line B--B of FIG. 4 and FIG. 7 is a cross sectional view taken along the line C--C of FIG. 4.

The first embodiment also employs the following construction of liquid crystal panel similar to that described in the conventional liquid crystal display device. That is, the liquid crystal panel of the first embodiment is constructed such that a red color pixel 101R, a green color pixel 101G and a blue color pixel 101B are disposed in this order in a direction in which a scanning signal line extends. In each pixel, a thin film transistor (TFT) 102 is formed. The thin film transistor 102 consists of a gate electrode 103a projecting from a gate line 103 as the scanning signal line and a drain electrode 104a projecting from a drain line 104 that extends in a direction perpendicular to the gate line. The gate line 103 and the gate electrode 103a are formed on a transparent substrate 100a and further, an insulation film 105 is formed on the transparent substrate 100a covering the gate line 103 and the gate electrode 103a. The drain line 104 is formed on the insulation film 105. An amorphous silicon layer 106 is formed on the insulation film 105 to face the gate electrode 103a and the drain electrode 104a is formed extending on the amorphous silicon layer 106. Furthermore, a source electrode 107 is formed extending from the amorphous silicon layer 106 in a direction apart from the drain electrode 104a while a part of the source electrode is at least positioned on and inside the amorphous silicon layer.

Furthermore, in the embodiment, each pixel is partitioned into, for instance, nearly two equal sections, i.e., a reflective display section R and a transmissive display section T, by a line extending in parallel with the scanning signal line. In this case, the reflective display section R is disposed in a pixel in a section thereof including the thin film transistor 102.

Moreover, within the reflective display section R of each pixel, projecting portions 8 are formed on the insulation film 105. The projecting portions 8 consist of, for example, an insulation film. In addition, an insulation film 10 is formed covering the projecting portions 8, the thin film transistor 102 and the like and further, a contact hole 11 is formed in the insulation film 10 so as to reach the surface of the source electrode 107. Furthermore, in the reflective display section R, a reflective electrode 12 is formed within the contact hole 11 and on the insulation film 10. The reflective electrode 12 has a convex-concave surface reflecting the profile of the projecting portions 8. On the other hand, within the transmissive display section T, a transparent electrode 9 is formed on the insulation film 10 and the reflective electrode 12 and the transparent electrode 9 overlap each other around the boundary between the reflective display section R and the transmissive display section T. Additionally, a retardation film 113 and a polarizer 114 are formed on the transparent substrate 100a on a side thereof defined as the surface on which elements such as the thin film transistor 102 are not formed. The elements constructed as described above constitute a TFT substrate.

Moreover, another transparent substrate 100b is disposed in parallel with the transparent substrate 100a on a side thereof defined as the surface on which the thin film transistor 102 is formed. A color filter (CF) 21 is formed on a surface of the transparent substrate 100b on a side thereof facing the transparent substrate 100a. As shown in FIGS. 4 through 7, the color filter 21 is formed extending in parallel with the drain line 104 and further, when viewing a pixel in a direction perpendicular to a surface of the associated transparent substrate, the transparent electrode 9 and the reflective electrode 12 are formed inside with respect to both end lines of the color filter 21. In addition, within the reflective display section R, slits 21a are formed in the color filter 21. The slits 21a are formed to have a width of, for instance, 1 .mu.m to 10 .mu.m and further, to occupy, for instance, below 50% of an area of the color filter 21 within the reflective display section R. Note that the ratio of an area occupied by the slits 21a with respect to an area of the color filter 21 within the reflective display section R varies depending on a color to be displayed and in the embodiment, the ratio of an area occupied by the slits 21a that are formed in the green color pixel 101G is made, for example, three times the respective ratio of an area occupied by the slits 21a that are formed in the red color pixel 101R and the blue color pixel 101B. Note that although the embodiment is constructed such that the slits 21a are formed extending in a direction in parallel with the color filter 21, the embodiment is not limited to the above-described construction of slits and therefore, may be constructed by employing another slits that have patterns different from that of the slits 21a.

Furthermore, an overcoat layer 25 is formed on the transparent substrate 100b filling the slits 21a while covering the color filter 21 and an opposing electrode 122 is formed on the overcoat layer 25. The overcoat layer 25 consists of, for example, a transparent resin and the opposing electrode 122 consists of, for example, an ITO (Indium Tin Oxide). A retardation film 123 and a polarizer 124 are formed on a surface of the transparent substrate 100b on a side thereof defined as the surface on which elements such as the color filter 21 are not formed. The elements constructed as described above constitute a CF substrate.

Subsequently, a liquid crystal 130 is interposed between the TFT substrate and the CF substrate.

In the first embodiment constructed as described above, in the transmissive display section T, a light emitted from a backlight (not shown) exits to the outside through the color filter 21. In the reflective display section R, a part of a light reaching the reflective electrode 12 through the color filter 21 exits to the outside through the slits 21a and a part of a light reaching the reflective electrode 12 through the slits 21a exits to the outside through the color filter 21. Also, the following phenomenon can be seen in the reflective display section R. That is, a light reaching the reflective electrode 12 through the color filter 21 exits to the outside through the color filter 21 and a light reaching the reflective electrode 12 through the slits 21a exits to the outside through the slits 21a. Therefore, a mean film thickness of a color filter through which lights exiting from the reflective display section R transmit during the time in which the lights travel the associated distance after they are inputted to the inside until they are outputted to the outside becomes nearly equal to that could be observed in the transmissive region T. In addition, as the embodiment employs the ratio of an area of the slits 21a with respect to an area of the color filter within the reflective display section R (hereinafter, the ratio is referred to as "aperture ratio") varying depending on a color to be displayed, it is possible to make the color reproduction ranges of the reflective display section R and the transmissive display section T coincide with each other with respect to a color to be displayed. As a result, the color liquid crystal display panel constructed as described above can display high quality images.

Subsequently, the relationship between an aperture ratio and a color balance will be explained below.

The inventors of this application carried out a simulation in the following manner to make the above-described relationship clearer: first, decide to use a white-colored light emitting diode (LED) as a backlight; secondly, vary the film thickness of color filter; thirdly, with respect to various film thicknesses of color filter, calculate the aperture ratio so as to take the value for allowing chromaticity coordinates of the transmissive display section to substantially match to the CIE (Center for International Education) chromaticity coordinates of a white display. In this case, a standard light CIE "C" was used as a light incident on the reflective display section. FIG. 8 is a graphic illustration of a spectrum of the standard light CIE "C" and FIG. 9 is a graphic illustration of a spectrum of a light emitted from a white-colored LED. Note that an intensity of light along the longitudinal axis shown in FIGS. 8 and 9 is normalized such that the maximum intensity of light takes the value of one. The results obtained by carrying out the above-mentioned simulation will be illustrated in the following Tables 1 through 7.

TABLE-US-00001 TABLE 1 Film thickness 0.8 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.417 0.328 display Green -- 0.329 0.377 section Blue -- 0.229 0.288 White -- 0.321 0.366 0.040 Reflective Red 0.20 0.417 0.319 display Green 0.38 0.319 0.378 section Blue 0.27 0.239 0.288 (having White -- 0.318 0.334 0.042 optimal slits) Reflective Red 0 0.487 0.306 display Green 0 0.316 0.417 section Blue 0 0.171 0.247 (having no White -- 0.311 0.336 0.142 slits)

TABLE-US-00002 TABLE 2 Film thickness 1.0 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.430 0.328 -- display Green -- 0.328 0.385 -- section Blue -- 0.217 0.279 -- White -- 0.321 0.337 0.054 Reflective Red 0.18 0.430 0.320 -- display Green 0.37 0.318 0.385 -- section Blue 0.24 0.231 0.280 -- (having White -- 0.318 0.335 0.055 optimal slits) Reflective Red 0 0.508 0.308 -- display Green 0 0.314 0.435 -- section Blue 0 0.161 0.236 -- (having no White -- 0.311 0.341 0.183 slits)

TABLE-US-00003 TABLE 3 Film thickness 1.2 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.443 0.328 -- display Green -- 0.328 0.393 -- section Blue -- 0.206 0.271 -- White -- 0.320 0.338 0.069 Reflective Red 0.17 0.440 0.322 -- display Green 0.36 0.317 0.392 -- section Blue 0.20 0.219 0.271 -- (having White -- 0.317 0.336 0.069 optimal slits) Reflective Red 0 0.527 0.310 -- display Green 0 0.311 0.451 -- section Blue 0 0.153 0.227 -- (having no White -- 0.311 0.345 0.224 slits)

TABLE-US-00004 TABLE 4 Film thickness 1.4 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.455 0.328 -- display Green -- 0.327 0.401 -- section Blue -- 0.196 0.263 -- White -- 0.319 0.338 0.086 Reflective Red 0.15 0.454 0.323 -- display Green 0.35 0.316 0.398 -- section Blue 0.15 0.204 0.258 -- (having White -- 0.316 0.336 0.088 optimal slits) Reflective Red 0 0.544 0.313 -- display Green 0 0.309 0.467 -- section Blue 0 0.147 0.219 -- (having no White -- 0.311 0.348 0.264 slits)

TABLE-US-00005 TABLE 5 Film thickness 1.6 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.473 0.329 -- display Green -- 0.327 0.408 -- section Blue -- 0.185 0.252 -- White -- 0.319 0.339 0.108 Reflective Red 0.12 0.476 0.324 -- display Green 0.31 0.314 0.409 -- section Blue 0.14 0.200 0.251 -- (having White -- 0.317 0.339 0.111 optimal slits) Reflective Red 0 0.566 0.316 -- display Green 0 0.306 0.482 -- section Blue 0 0.141 0.209 -- (having no White -- 0.312 0.353 0.310 slits) Reflective Red 0.20 0.440 0.327 -- display Green 0.20 0.312 0.429 -- section Blue 0.20 0.218 0.264 -- (having White -- 0.316 0.346 0.097 constant aperture ratio regardless of a color to be displayed)

TABLE-US-00006 TABLE 6 Film thickness 1.8 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.490 0.330 -- display Green -- 0.326 0.416 -- section Blue -- 0.175 0.243 -- White -- 0.319 0.340 0.131 Reflective Red 0.11 0.488 0.327 -- display Green 0.30 0.313 0.414 -- section Blue 0.11 0.189 0.240 -- (having White -- 0.317 0.340 0.130 optimal slits) Reflective Red 0 0.584 0.320 -- display Green 0 0.304 0.496 -- section Blue 0 0.136 0.201 -- (having no White -- 0.312 0.356 0.354 slits)

TABLE-US-00007 TABLE 7 Film thickness 2.0 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.506 0.331 -- display Green -- 0.325 0.423 -- section Blue -- 0.167 0.234 -- White -- 0.319 0.341 0.154 Reflective Red 0.09 0.506 0.328 -- display Green 0.28 0.312 0.421 -- section Blue 0.10 0.186 0.234 -- (having White -- 0.318 0.343 0.152 optimal slits) Reflective Red 0 0.599 0.323 -- display Green 0 0.301 0.508 -- section Blue 0 0.133 0.194 -- (having no White -- 0.313 0.360 0.394 slits)

It should be noted that the NTSC ratio is a ratio of an area of a color reproduction range of the associated display section with respect to an area of a color reproduction range most suitable for television display and defined by NTSC (National Television System Committee). FIG. 10 is a CIE chromaticity diagram showing a color reproduction range most suitable for television display and defined by NTSC.

As shown in the above-described Tables 1 through 7, in a case where slits are formed in the color filter to make the color filter have the appropriate aperture ratio, the chromaticity coordinates and NTSC ratio calculated with respect to the transmissive display section substantially match to those calculated with respect to the reflective display section. On the other hand, in a case where slits are not formed in the color filter within the reflective display section, the chromaticity coordinates and NTSC ratio calculated with respect to the transmissive display section are extensively different from those calculated with respect to the reflective display section. Furthermore, also in a case where slits are formed in the color filter to make the color filter have the same aperture ratio within the reflective display section regardless of a color to be displayed, as shown in Table 5, difference in the color reproduction ranges of respective display sections is not large. However, as the saturations of color observed in a green color pixel increase whereas the saturations of color observed in a red color pixel and a blue color pixel decrease, difference in respective hues observed in the transmissive display section and the reflective display section results.

Furthermore, the inventors of this application carried out a simulation in the following manner: first, decide to use a three-wavelength light source (the first three-wavelength light source) as a backlight; secondly, vary the film thickness of color filter; thirdly, with respect to various film thicknesses of color filter, calculate the aperture ratio so as to take the value for allowing chromaticity coordinates of the transmissive display section to substantially match to the CIE (Center for International Education) chromaticity coordinates. In this case, a standard light CIE "C" was used as a light incident on the reflective display section. FIG. 11 is a graphic illustration of a spectrum of the light emitted from the first three-wavelength light source. Note that an intensity of light along the longitudinal axis shown in FIG. 11 is normalized such that the maximum intensity of light takes the value of one. The results obtained by carrying out the above-mentioned simulation will be illustrated in the following Tables 8 through 10.

TABLE-US-00008 TABLE 8 Film thickness 1.2 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.447 0.291 -- display Green -- 0.335 0.387 -- section Blue -- 0.216 0.252 -- White -- 0.329 0.317 0.084 Reflective Red 0.15 0.448 0.321 -- display Green 0.40 0.317 0.387 -- section Blue 0.10 0.191 0.252 -- (having White -- 0.313 0.331 0.082 optimal slits)

TABLE-US-00009 TABLE 9 Film thickness 1.6 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.476 0.292 -- display Green -- 0.333 0.407 -- section Blue -- 0.197 0.234 -- White -- 0.330 0.320 0.128 Reflective Red 0.12 0.476 0.324 -- display Green 0.31 0.314 0.409 -- section Blue 0.08 0.178 0.236 -- (having White -- 0.314 0.337 0.124 optimal slits) Reflective Red 0.15 0.461 0.326 -- display Green 0.15 0.311 0.440 -- section Blue 0.15 0.204 0.254 -- (having White -- 0.315 0.347 0.127 constant aperture ratio regardless of a color to be displayed)

TABLE-US-00010 TABLE 10 Film thickness 2.0 .mu.m x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.507 0.296 -- display Green -- 0.332 0.426 -- section Blue -- 0.182 0.214 -- White -- 0.331 0.324 0.179 Reflective Red 0.08 0.514 0.328 -- display Green 0.26 0.311 0.425 -- section Blue 0.05 0.162 0.216 -- (having White -- 0.315 0.342 0.18 optimal slits)

As shown in the above-indicated Tables 8 through 10, in a case where slits are formed in the color filter to make the color filter have an appropriate aperture ratio, the chromaticity coordinates and NTSC ratio calculated with respect to the transmissive display section substantially match to those calculated with respect to the reflective display section even when the light source used in the simulation changes. On the other hand, in a case where slits are formed in the color filter to make the color filter have the same aperture ratio regardless of a color to be displayed, as shown in Table 9, difference in the color reproduction ranges of respective display sections is not large. However, as the saturations of color observed in a green color pixel increase whereas the saturations of color observed in a red color pixel and a blue color pixel decrease, difference in respective hues observed in the transmissive display section and the reflective display section results.

In the following description, relationship between an aperture ratio and a light source will be explained. When a spectrum of a light emitted from the light source varies, the chromaticity coordinates of a light exiting to the outside through a color filter within a transmissive display section vary correspondingly. This explanation will also be understood by comparing the figures of associated items indicated in the above-described Tables 1 through 7 with the figures of associated items indicated in the above-described Tables 8 through 10. To make the relationship between an optimal aperture ratio and a light source clearer, the inventors carried out a simulation. In the simulation, the film thickness of a color filter is fixed to be 1.6 .mu.m and the aforementioned white-colored LED, the first three-wavelength light source and an additional three-wavelength light source (the second three-wavelength light source) are employed as a light source. FIG. 12 is a graphic illustration of a spectrum of a light emitted from the second three-wavelength light source. Note that an intensity of light along the longitudinal axis shown in FIG. 12 is normalized such that the maximum intensity of light takes the value of one. The results obtained by carrying out the above-mentioned simulation will be illustrated in the following Tables 11 through 13 in which the white-colored LED, the first three-wavelength light source and the second three-wavelength light source are employed, respectively.

TABLE-US-00011 TABLE 11 x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.473 0.329 -- display section Green -- 0.327 0.408 -- Blue -- 0.185 0.252 -- White -- 0.319 0.339 0.108 Reflective Red 0.12 0.476 0.324 -- display section Green 0.31 0.314 0.409 -- (having optimal Blue 0.14 0.200 0.251 -- slits) White -- 0.317 0.339 0.111

TABLE-US-00012 TABLE 12 x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.476 0.292 -- display section Green -- 0.333 0.407 -- Blue -- 0.197 0.234 -- White -- 0.330 0.320 0.128 Reflective Red 0.12 0.476 0.324 -- display section Green 0.31 0.314 0.409 -- (having optimal Blue 0.08 0.178 0.236 -- slits) White -- 0.314 0.337 0.124

TABLE-US-00013 TABLE 13 x y Aperture coordinate coordinate NTSC Hue ratio value value ratio Transmissive Red -- 0.437 0.286 -- display section Green -- 0.311 0.428 -- Blue -- 0.195 0.243 -- White -- 0.303 0.331 0.126 Reflective Red 0.20 0.440 0.327 -- display section Green 0.20 0.312 0.429 -- (having optimal Blue 0.10 0.186 0.241 -- slits) White -- 0.311 0.343 0.116

As shown in Table 13, in the case where the second three-wavelength light source is employed in the simulation, an optimal color reproduction range is obtained when aperture ratios applied to a red color filter and a green color filter coincide with each other.

The results obtained by those simulations tell that regardless of a light source to be employed in the simulation, it is desirable to make the aperture ratio applied to the green color filter largest among three aperture ratios applied to the red, green and blue color filters. Specifically, in the case where a white-colored light source is employed in the simulation, it is preferable that the aperture ratio applied to the green color filter is made two to four times those applied to the red and blue color filters.

It should be noted that it is preferable that the slits of the color filter are formed to have a width of 1 .mu.m to 10 .mu.m. When the slits are formed to have a width narrower than 1 .mu.m, operation for forming associated patterns in the color filter becomes difficult. On the other hand, when the slits are formed to have a width wider than 10 .mu.m, operation for flattening an overcoat layer formed on the color filter becomes difficult.

As already mentioned in the above-described explanation, the openings of the color filter is not limited to the above-described slits and therefore, may be constructed by employing another openings that have patterns different from those of the slits. Furthermore, a positional relationship relatively observed between the reflective display section and the transmissive display section is not limited to the above-described construction of reflective display and transmissive display sections. FIGS. 13A, 13B and 13C are plan views illustrating patterns of various color filters and positional relationship between reflective display and transmissive display sections within a pixel.

For instance, as shown in FIG. 13A, in the case where the reflective display section R and the transmissive display section T are partitioned in the same manner shown in the above-described embodiment, the liquid crystal panel of the present invention may employ an opening 41a that is formed in the color filter 41 so as to be positioned in the center of the reflective display section R.

In addition, as shown in FIG. 13B, also in a case where the reflective display section R and the transmissive display section T are partitioned such that the reflective display section R is surrounded by the transmissive display section T, the liquid crystal panel of the present invention may employ an opening 42a that is formed in a color filter 42 so as to be positioned in the center of the reflective display section R.

Moreover, as shown in FIG. 13C, in a case where the reflective display section R and the transmissive display section T are partitioned such that the transmissive display section T is interposed between the two reflective display sections R, the liquid crystal panel of the present invention may employ the following construction of pixel. That is, the pixel is constructed such that a color filter 43 is formed to have its end lines 43a positioned nearer the transmissive display section T than the outer end lines of the two reflective display sections R, thereby creating regions in the pixel in which the color filter 43 is not formed.

It should be noted that regardless of a pattern of color filter, it is preferable that the ratio of an area of openings with respect to that of the reflective display section is made equal to or less than 50%. In other words, it would be desirable to form the color filter so as to occupy at least 50% of an entire area of the reflective display section. The reason is as follows. That is, when the color filter is formed to occupy less than 50% of an entire area of the reflective display section, the ratio of lights that have no opportunities to transmit through the color filter during the time in which the lights travel the associated distance after they are inputted to the inside until they are outputted to the outside with respect to entire lights associated with the reflective display section increases, thereby making it difficult for the color reproduction range of the reflective display section to coincide with that of the transmissive display section.

The second embodiment of the present invention will be described below. In the second embodiment, the film thickness of color filter within a reflective display section is made thinner than that within a transmissive display section. FIGS. 14, 15 and 16 are cross sectional views, each illustrating a structure of a liquid crystal panel of the second embodiment constructed in accordance with the present invention, taken along the line A--A of FIG. 4, the line B--B of FIG. 4 and the line C--C of FIG. 4, respectively. Note that the parts and components used in the second embodiment shown in FIGS. 14, 15, 16 and also used in the first embodiment shown in FIGS. 4, 5, 6, 7, 8 are denoted by the same numerals as those referred in the first embodiment, thereby omitting detailed explanation thereof.

The second embodiment also includes the following construction of liquid crystal panel similar to that described in the first embodiment. That is, the liquid crystal panel of the second embodiment is constructed such that each pixel is partitioned into, for example, nearly two equal sections, i.e., a reflective display section R and a transmissive display section T, by a line extending in parallel with the scanning signal line. Furthermore, a TFT substrate is constructed in the same manner as that employed in the first embodiment.

A CF substrate of the second embodiment is constructed such that a color filter 51 is formed on a surface of a transparent substrate 100b on a side thereof facing a transparent substrate 100a. In addition, within the reflective display section R, a transparent resin layer 52 is formed between the color filter 51 and the transparent substrate 100b. In this case, the ratio of a volume of the transparent resin layer 52 with respect to an entire volume of the color filter 51 and the transparent resin layer 52 within the reflective display section R (hereinafter, the ratio is referred to as "volume ratio") is set at a value of, for example, 35% to 65%. The volume ratio can be adjusted by varying a film thickness or an area of the transparent resin layer 52. Note that the volume ratio varies depending on a color to be displayed and in the embodiment, the volume ratio applied to a green color pixel 101G is made, for example, about three times the volume ratio applied to a red color pixel 101R and a blue color pixel 101B. Furthermore, although the embodiment is constructed such that the transparent resin layer 52 is formed completely overlapping the color filter 51, the embodiment is not limited to the above-described construction of transparent resin layer and color filter. Additionally, it would be desirable that the color filter 51 has a flat surface in the same plane over two areas thereof corresponding to the reflective display section R and the transmissive display section T.

In the liquid crystal panel of the second embodiment constructed as described above, within the transmissive display section T, a light emitted from a backlight (not shown) exits to the outside through the color filter 51. Within the reflective display section R, a light reaching the reflective electrode 12 through the color filter 51 exits to the outside through the color filter 51. In this case, as the film thickness of the color filter 51 within the reflective display section R is being made approximately half that of the color filter 51 within the transmissive display section T, the substantial film thickness of color filter through which lights transmit during the time in which the lights travel the associated distance after they are inputted to the inside until they are outputted to the outside becomes nearly equal to that could be observed within the transmissive display section T. Furthermore, in the embodiment, as the volume ratio calculated with respect to the volume of the transparent resin layer 52 is made to vary depending on a color to be displayed, it becomes possible for the color reproduction range of the reflective display section R to coincide with that of the transmissive display section T, thereby allowing the liquid crystal panel to display high quality images.

Subsequently, the relationship between a volume ratio and a color balance will be explained below. The inventors of this application carried out the simulation similar to that performed in the first embodiment to make the above-described relationship clearer: first, decide to use a white-colored LED as a backlight; secondly, vary the film thickness of color filter and at the same time, vary the area of transparent resin layer; thirdly, with respect to various film thicknesses of color filter, calculate the volume ratio so as to take the value for allowing chromaticity coordinates of the transmissive display section to substantially match to the CIE (Center for International Education) chromaticity coordinates. In this case, a standard light CIE "C" is used as a light incident on the reflective display section. The results obtained through the above-described simulation will be indicated in the following Tables 14 and 15.

TABLE-US-00014 TABLE 14 Film thickness 2.2 .mu.m x y Area Volume coordinate coordinate NTSC Hue ratio ratio value value ratio Transmissive Red -- -- 0.518 0.333 display Green -- -- 0.325 0.43 section Blue -- -- 0.161 0.227 White -- -- 0.319 0.342 0.175 Reflective Red 0.82 0.58 0.51 0.309 display Green 0.98 0.41 0.314 0.427 section Blue 0.70 0.48 0.158 0.23 (having White -- -- 0.313 0.34 0.18 optimal transparent resin layer)

TABLE-US-00015 TABLE 15 Film thickness 2.0 .mu.m x y Area Volume coordinate coordinate NTSC Hue ratio ratio value value ratio Transmissive Red -- -- 0.506 0.331 display Green -- -- 0.325 0.423 section Blue -- -- 0.167 0.234 White -- -- 0.319 0.341 0.154 Reflective Red 0.80 0.60 0.501 0.308 display Green 1.00 0.42 0.316 0.417 section Blue 0.70 0.48 0.163 0.235 (having White -- -- 0.313 0.337 0.158 optimal transparent resin layer)

It should be noted that "area ratio" indicated in the tables represents the ratio of an area of transparent resin layer with respect to an area of color filter within the reflective display section and "volume ratio" represents the ratio of a volume of transparent resin layer with respect to an entire volume of color filter and transparent resin layer within the reflective display section. In addition, "film thickness" represents a film thickness of color filter within the transmissive display section, coinciding with an entire film thickness of color filter and transparent resin layer within the reflective display section.

As indicated in the above-described Tables 14 and 15, in a case where a transparent resin layer is formed within the reflective display section to have an appropriate volume ratio, the chromaticity coordinates and NTSC ratio calculated with respect to the transmissive display section substantially match to those calculated with respect to the reflective display section.

A method for manufacturing the liquid crystal panel of the first embodiment will be explained below. A TFT substrate can be manufactured by using the same method as that employed to manufacture the conventional liquid crystal panel. On the other hand, a CF substrate can be manufactured using, for instance, the following method: first, coat a photosensitive resin film as a raw material film that constitutes a monochrome color filter on a transparent substrate 100b; secondly, expose the photosensitive resin film using a photomask that has a predetermined slit pattern therein and then, develop the photosensitive resin film. Through those steps, the photosensitive resin film is patterned to constitute a monochrome color filter 21 having slits 21a therein. Those steps are carried out to form three color filters 21 respectively. Note that the ratio of an area of a pattern to be formed in the photomask corresponding to the slits with respect to an area of the photomask, for example, is made maximum when using a photomask to form a green color filter. That is, the ratios applied to the associated color filters are individually adjusted. In other words, the photomasks are individually formed to have a pattern associated with a slit pattern formed in the color filter and corresponding to a color to be displayed. In a case where a white-colored light source is employed in the liquid crystal display device, it is preferable that the ratio of an area of slit pattern with respect to an area of the photomask used to form a green color filter is made about two to four times that should be applied to a photomask to form a red or blue color filter.

After formation of three color filters, an overcoat layer is formed on an entire surface of the transparent substrate 100b while achieving flatness thereof and further, an opposing electrode is formed ther