Abstract:
A liquid crystal display device, which has a pair of substrates and a liquid crystal layer held therebetween, includes a transmission display region for performing image display by transmission light and a reflection display region for performing image display by reflection light. The display device is provided with a data line for supplying a signal to a drive element adapted to drive the liquid crystal layer, and is characterized in that a section, adjacent to the transmission display region, of the data line is formed on a plane different from a plane on which a section, adjacent to the reflection display region, of the data line is formed. Such a display device is advantageous in suppressing enlargement of an ineffective region in the vicinity of a section, adjacent to a data line, of a transmission display region, even if the transmission display region is enlarged for enhancing the brightness of transmission display, thereby realizing a desirable display quality.

Description:
This application claims priority to Japanese Patent Application No. JP2002-113833 filed Aug. 16, 2002 which are incorporated herein by reference. 
   BACKGROUND OF THE INVENTION 
   The present invention relates to a liquid crystal display device, and particularly to an improvement of a reflection-transmission hybrid type liquid crystal display device. 
   Taking advantage of thin shape and low power consumption, liquid crystal display devices have been extensively used for laptop personal computers, display units for car navigation, portable information terminals (PDAs: Personal Digital Assistants), and cellular telephones. These liquid crystal display devices are generally classified into a transmission type and a reflection type. In the transmission type, image display is performed by switching the on/off state of light by a liquid crystal panel, wherein the light has been emitted from an internal light source called “backlight” and enters the liquid crystal panel, and a reflection type in which image display is performed by switching the on/off state of external light such as sun light by a liquid crystal panel, wherein the external light has been reflected from a reflection plate or the like and enters the liquid crystal panel. 
   The transmission type liquid crystal display device, however, has problems that since the power consumption of the backlight is as large as 50% or more of the total power consumption of the display device, the total-power consumption of the display device is increased by using the backlight, and that when the surrounding environment is bright, an image displayed by the light is dark, to degrade the visibility of the image. 
   The reflection type liquid crystal display device overcomes the problem associated with the increased power consumption because the display device is provided with no backlight; however, such a display device has a problem that when the surrounding environment is dark, the amount of reflected light is reduced, to significantly degrade the visibility of an image displayed by the reflected light. 
   To solve the problems of both the transmission type liquid crystal display device and the reflection type liquid crystal display device, there has been proposed a reflection-transmission hybrid type liquid crystal display device intended to realize both the transmission display mode and the reflection display mode by one liquid crystal panel. In this reflection-transmission hybrid type liquid crystal display device, when the surrounding environment is bright, display (reflection display) is performed by using external light reflected from a reflection plate or the like, and when the surrounding environment is dark, display (transmission display) is performed by using light emitted from a backlight. Such a reflection-transmission hybrid type liquid crystal display device has been disclosed, for example, in Japanese Patent No. 2955277 and Japanese Patent Laid-open No. 2001-166289. 
     FIG. 6  is a plan view showing a planar structure of a thin film transistor (hereinafter, referred to as “TFT”) substrate  102  of a related art reflection-transmission hybrid type liquid crystal display device  101 . Referring to this figure, a plurality of pixel electrodes  103  controlled by TFTs (to be described later) are arranged in a matrix on the TFT substrate  102 , and gate lines  104  for supplying scanning signals to the TFTs and data lines  105  for supplying display signals to the TFTs are provided in perpendicular to each other on the TFT substrate  102  in such a manner as to surround the pixel electrodes  103 , to form pixel regions. 
   Auxiliary capacitance lines (hereinafter, referred to as “Cs lines”)  106  made from a metal film are provided on the TFT substrate  102  in such a manner as to be in parallel to the gate lines  104 . As will be described later, the Cs line  106  forms an auxiliary capacitance C between a connection electrode and the same, and is connected to a counter electrode provided on a color filter substrate. 
   A reflection display region A for reflection display and a transmission display region B for transmission display are provided in each of the pixel electrodes  103 . 
     FIG. 7  shows a cross-sectional structure of the liquid crystal display device  101  along line F—F′ of FIG.  6 . The liquid crystal display device has a structure that the above-described TFT substrate  102  and a color filter substrate  107  are disposed in such a manner as to face to each other with a liquid crystal layer  108  held therebetween. 
   The color filter substrate  107  has a structure that a color filter  110  and a counter electrode  111  made from ITO (Indium Tin Oxide) or the like are arranged in this order on a surface, facing to the TFT substrate  102 , of a transparent insulating substrate  109  made from glass or the like. The color filter  110  is a resin layer portion colored into respective colors by pigments or dyes, and is typically composed of a combination of filter layers of colors of R (red), G (green), and B (blue). 
   A quarter wavelength (λ/4) layer  112  and a polarizing plate  113  are arranged on a surface, opposed to the surface provided with the color filter  110  and the counter electrode  111 , of the color filter substrate  107 . 
   In the reflection display region A of the TFT substrate  102 , there are formed TFTs  115 , a scattering layer  116 , a planarizing layer  117 , and a reflection electrode  119  on a transparent insulating substrate  114  made from a transparent material such as glass. The TFTs  115  function as switching elements for supplying display signals to the pixel electrodes  103 . The scattering layer  116  is formed on the TFTs  115  via a multi-layer insulating film (to be described in detail later). The planarizing layer  117  is formed on the scattering layer  116 . The reflection electrode  119  is formed on the planarizing layer  117  via an ITO film  118   a.    
   The TFT  115  shown in  FIG. 7  is of a so-called bottom gate structure including a gate electrode  120 , a gate insulating film  121 , and a semiconductor thin film  122 . The gate electrode  120  is formed on the transparent insulating substrate  114 . The gate insulating film  121  is composed of a multi-layer film having a silicon nitride film  121   a  and a silicon oxide film  121   b  stacked on the upper surface of the gate electrode  120 . The semiconductor thin film  122  is formed on the gate insulating film  121 , wherein regions, on both sides of the gate electrode  120 , of the semiconductor thin film  122  are taken as N +  diffusion regions. The gate electrode  120  is formed by extending part of the gate line  104 , and is made from a metal such as molybdenum (Mo) or tantalum (Ta) or an alloy thereof by sputtering or the like. 
   A contact hole is formed in both a first interlayer insulating film  123  and a second interlayer insulating film  124  at a position corresponding to that of one of the N +  diffusion regions of the semiconductor thin film  122 . A source electrode  125  is-connected to the one of the N +  diffusion regions of the semiconductor thin film  122  via the contact hole. The data line  105  is connected to the source electrode  125 . A data signal is inputted to the source electrode  125  via the data line  105 . Another contact hole is formed in both the first interlayer insulating film  123  and the second interlayer insulating film  124  at a position corresponding to that of the other of the N +  diffusion regions of the semiconductor thin film  122 . A drain electrode  126  is connected to the other of the N +  diffusion regions of the semiconductor thin film  122  via the contact hole. The drain electrode  126  is connected to a connection electrode  127 , and is electrically connected to the pixel electrode  103  via a contact portion  128 . The connection electrode  127  forms the auxiliary capacitance C between the Cs line  106  and the same via the gate insulating film  121 . The semiconductor thin film  122  is made from low temperature polysilicon, for example, by a CVD (Chemical Vapor Deposition) process. The semiconductor thin film  122  is formed at a position aligned with that of the gate electrode  120  via the gate insulating film  121 . 
   A stopper  129  is provided directly over the semiconductor thin film  122  via the first interlayer insulating film  123  and the second interlayer insulating film  124 . The stopper  129  is adapted to protect the semiconductor thin film  122  formed at the position aligned with that of the gate electrode, 120 . 
   In the transmission display region B of the TFT substrate  102 , various insulating films formed substantially over the entire surface of the reflection display region A, that is, the gate insulating film  121 , the first interlayer insulating film  123 , the second interlayer insulating film  124 , the scattering layer  116 , and the planarizing layer  117  are removed, and a transparent electrode  118  is directly formed on the transparent insulating substrate  114 . The reflection electrode  119  formed in the reflection display region A is not formed in the transmission display region B, either. 
   Like the color filter substrate  107 , a λ/4 layer  130  and a polarizing plate  131  are disposed in this order on a surface, on the side opposed to that provided with the TFTs  115  and the like, of the TFT substrate  102 , that is, on the side provided with a backlight as an internal light source (not shown), of the TFT substrate  102 . 
   In the related art reflection-transmission hybrid type liquid crystal display device  101  having the above-described configuration, high quality image display can be realized in either the reflection display mode or the transmission display mode because the thickness of the liquid crystal layer  108  in the reflection display region A is different from that of the liquid crystal layer  108  in the transmission display region B. 
   A difference-in-height between the reflection display region A and the transmission display region B in each pixel region on the TFT substrate  102  is typically set to about 2 μm. As shown in  FIG. 7 , such a difference-in-height portion has a sharp gradient, to cause problems that liquid crystal domains are liable to occur at a boundary region (equivalent to the difference-in-height portion) between the reflection display region A and the transmission display region B, and that since a gap (thickness of the liquid crystal layer) at the difference-in-height portion satisfies neither a gap required for reflection display nor a gap required for transmission display, the difference-in-height portion contributes neither reflection display nor transmission display, whereby leakage of light may occur at the difference-in-height portion. The region contributing to neither reflection display nor transmission display is hereinafter referred to as “ineffective region”. The ineffective region degrading the display quality is generally required to be shielded by a shield film or the like. 
   By the way, in recent years, to realize more highly precise image display, there has been proposed a liquid crystal display device having a structure that the transmission display region B contributing to transmission display is broadened as shown in FIG.  8 . 
   As a result of broadening the transmission display region B, in each pixel region surrounded by the data lines  105  and the gate lines  104 , sections, positioned on both sides of the transmission region A in the direction parallel to the gate line, of the reflection display region A are relatively narrowed. As a result, the transmission display region B becomes close to the data line  105 , as shown in  FIG. 8 , in the direction parallel to the gate line  104  (horizontal direction in the figure). 
   In the case where the transmission display region B is separated apart from the data line  105  as shown in  FIG. 6 , the difference-in-height between the reflection display region A and the transmission display region B in each of the direction parallel to the data line (vertical direction in  FIG. 6 ) and the direction parallel to the gate line (horizontal direction in  FIG. 6 ) is, as shown in  FIG. 7 , equivalent to the total of the thicknesses of the gate insulating film  121 , the first interlayer insulting film  123 , the second interlayer insulating film  124 , the scattering layer  116 , the planarizing layer  117 , and the reflection electrode  119 . On the other hand, in the case where the transmission display region B becomes close to the data line  105  as shown in  FIG. 8 , the difference-in-height between the reflection display region A and the transmission display region B in the direction parallel to the data line (vertical direction) is the same as that described above; however, the difference-in-height between the reflection display region A and the transmission display region B in the direction parallel to the gate line (horizontal direction) substantially becomes the difference-in-height between the data line region and the transmission display region B because the section, between the transmission display region B and the data line  105 , of the reflection display region A is very narrow. By the way, the thickness of the data line region is a value obtained by adding the thickness of the data line  105  to the above-described total thickness. Accordingly, the difference-in-height between the data line region and the transmission display region B in the direction parallel to the gate line (horizontal direction) becomes large, with a result that it fails to obtain a gap (thickness of the liquid crystal layer) required for transmission display at such a difference-in-height. 
   As a result, the ineffective region becomes large in the section, adjacent to the data line  105 , of the transmission display region B, and thereby an effective region becomes relatively small, to cause a problem that desired brightness cannot be obtained in the transmission mode, although the transmission display region B is broadened. 
   SUMMARY OF THE INVENTION 
   An object of the present invention is to provide a reflection-transmission hybrid type liquid crystal display device capable of suppressing enlargement of an ineffective region in the vicinity of a section, adjacent to a data line, of a transmission display region, even if the transmission display region is enlarged for enhancing brightness of transmission display, thereby realizing desirable display quality. 
   To achieve the above object, according to the present invention, there is provided a liquid crystal display device including a pair of substrates and a liquid crystal layer held therebetween. The display device includes a transmission display region for performing image display by transmission light and a reflection display region for performing image display by reflection light. In this display device, a data line for supplying a signal to a drive element adapted to drive the liquid crystal layer is provided, and a section, adjacent to the transmission display region, of the data line is formed on a plane different from a plane on which a section, adjacent to the reflection display region, of the data line is formed. 
   With this configuration, since a section, adjacent to the transmission display region, of the data line is formed on a plane different from a plane on which a section, adjacent to the reflection display region, of the data line is formed, it is possible to reduce a difference-in-height between the transmission display region and the data line region-adjacent thereto as compared with the related art liquid crystal display device in which a section, adjacent to the transmission display region, of the date line and a section, adjacent to the reflection display region, of the data line are formed on the same plane. 
   As a result, even if the transmission display region is enlarged to the extent that a section, between the data line and the transmission display region, of the reflection display region is eliminated, it is possible to prevent enlargement of the ineffective region in the section, in the vicinity of the data line, of the transmission display region. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     These and other objects, features, and advantages of the present invention will becomes more apparent from the following detailed description, taken in connection with the accompanying drawings, in which: 
       FIG. 1  is a plan view of a TFT substrate of a reflection-transmission hybrid type liquid crystal display device of the present invention; 
       FIG. 2  is a sectional view taken on line C—C′ of  FIG. 1  showing an essential portion of the liquid crystal display device; 
       FIG. 3  is a sectional view taken on line D—D′ of  FIG. 1  showing an essential portion of the liquid crystal display device; 
       FIG. 4  is a sectional view taken on line E—E′ of  FIG. 1  showing an essential portion of the liquid crystal display device; 
       FIG. 5  is a sectional view taken on line E—E′ of  FIG. 1  showing another essential portion of the liquid crystal display device; 
       FIG. 6  is a plan view showing a TFT substrate of a related art reflection-transmission hybrid type liquid crystal display device; 
       FIG. 7  is a sectional view taken on line F—F′ of  FIG. 6  showing an essential portion of the related art liquid crystal display device; and 
       FIG. 8  is a plan view of the TFT substrate of the related art reflection-transmission hybrid type liquid crystal display device, with a transmission display region B enlarged. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Hereinafter, a liquid crystal display device of the present invention will be described in detail with reference to the accompanying drawings, in which preferred embodiments are shown. 
   A liquid crystal display device of the present invention is of a so-called reflection-transmission hybrid type of carrying out a reflection display mode and a transmission display mode on one display panel, and is configured such that a liquid crystal layer is held between a pair of substrates, that is, a TFT substrate provided with TFTs and the like and a color filter substrate provided with a color filter and the like. 
     FIG. 1  is a plan view showing a planar structure of a TFT substrate  2  of a reflection-transmission hybrid type liquid crystal display device  1  of the present invention. Referring to this figure, a plurality of pixel electrodes  3  controlled by TFTs (to be described later) are arranged in a matrix on the TFT substrate  2 , and gate lines  4  for supplying scanning signals to the TFTs and data lines  5  for supplying display signals to the TFTs are provided in perpendicular to each other around the pixel electrode  3 , to form pixel regions. 
   Cs lines  6  made from a metal film are also provided on the TFT substrate  2  in such a manner as to be in parallel to the gate lines  4 . As will be described later, the Cs line  6  forms an auxiliary capacitance C between a connection electrode and the same, and is connected to a counter electrode provided on a color filter substrate. 
   A reflection display region A for reflection display and a transmission display region B for transmission display are provided in each of the pixel electrodes  3 . 
     FIG. 2  is a sectional view taken on line C—C′ of  FIG. 1 , which line extends in parallel to the data line  5  while passing through an approximately central portion of the transmission display region B. 
   A cross-sectional structure of the liquid crystal display device of the present invention, taken on line C—C′ of  FIG. 1 , will be described with reference to FIG.  2 . 
   The liquid crystal display device  1 , has a structure that the above-described TFT substrate  2  and a color filter substrate  7  are disposed in such a manner as to face to each other with a liquid crystal  8  held therebetween. 
   The color filter substrate  7  has a structure that a color filter  10  and a counter electrode  11  made from ITO or the like are arranged in this order on a surface, facing to the TFT substrate  2 , of a transparent insulating substrate  9  made from glass or the like. The color filter  10  is a resin layer portion colored into respective colors by pigments or dyes, and is typically composed of a combination of filter layers of colors of R (red), G (green), and B (blue). 
   A λ/4 layer  12  and a polarizing plate  13  are arranged on a surface, opposed to the surface provided with the color filter  10  and the counter electrode  11 , of the color filter substrate  7 . 
   In the reflection display region A of the TFT substrate  2 , there are formed TFTs  15 , a scattering layer  16 , a planarizing layer  17 , and a reflection electrode  19  on a surface, facing to the color filter substrate  2 , of a transparent insulating substrate  14  made from a transparent material such as glass. The TFTs function as switching elements for supplying display signals to the pixel electrodes  3 . The scattering layer  16  is formed on the TFTs  15  via a multi-layer insulating film (to be described in detail later). The planarizing layer  17  is formed on the scattering layer  16 . The reflection electrode  19  is formed on the planarizing layer  17  via an ITO film  18   a . The scattering layer  16  and the planarizing layer  17  constitute an irregularity forming layer portion for changing the thickness of the TFT substrate  2  between the reflection display region A and the transmission display region B. The reflection electrode  19  is made from a metal such as rhodium, titanium, chromium, silver, aluminum, or a nickel-chromium alloy. Of these metal materials, silver is preferable because the metal increases the reflectivity in reflection display. 
   The TFT  15  shown in  FIG. 2  is of a so-called bottom gate structure including a gate electrode  20 , a gate insulating film  21 , and a semiconductor thin film  22 . The gate electrode  20  is formed on the transparent insulating substrate  14 . The gate insulating film  21  is composed of a multi-layer film having a silicon nitride film  21   a  and a silicon oxide film  21   b  stacked on the upper surface of the gate electrode  20 . The semiconductor thin film  22  is formed on the gate insulating film  21 , wherein regions, on both sides of the gate electrode  20 , of the semiconductor thin film  21  are taken as N +  diffusion regions. The gate electrode  20  is formed by extending part of the gate line  4 , and is made from a metal such as molybdenum (Mo) or tantalum (Ta) or an alloy thereof by sputtering or the like. 
   A contact hole is formed in both a first interlayer insulating film  23  and a second interlayer insulating film  24  at a position corresponding to that of one of the N +  diffusion regions of the semiconductor thin film  22 . A source electrode  25  is connected to the one of the N +  diffusion regions of the semiconductor thin film  22  via the contact hole. The data line  5  is connected to the source electrode  25 . A data signal is inputted to the source electrode  25  via the data line  5 . A contact hole is formed in both the first interlayer insulating film  23  and the second interlayer insulating film  24  at a position corresponding to that of the other of the N +  diffusion regions of the semiconductor thin film  22 . A drain electrode  26  is connected to the other of the N +  diffusion regions of the semiconductor thin film  22  via the contact hole. The drain electrode  26  is connected to a connection electrode  27 , and is electrically connected to the pixel electrode  3  via a contact portion  28 . The connection electrode  27  forms the auxiliary capacitance C between the Cs line  6  and the same via the gate insulating film  21 . The semiconductor thin film  22  is made from low temperature polysilicon, for example, by a CVD process. The semiconductor thin film  22  is formed at a position aligned with that of the gate electrode  20  via the gate insulating film  21 . 
   A stopper  29  is provided directly over the semiconductor thin film  22  via the first interlayer insulating film  23  and the second interlayer insulating film  24 . The stopper  29  is adapted to protect the semiconductor thin film  22  formed at a position aligned with that of the gate electrode  20 . 
   On the other hand, in the transmission display region B of the TFT substrate  2 , various insulating films formed substantially over the entire surface of the reflection display region A, that is, the gate insulating film  21 , the first interlayer insulating film  23 , the second interlayer insulating film  24 , the scattering layer  16 , and the planarizing layer  17  are removed. A transparent electrode  18  made from ITO or the like is directly formed on the transparent insulating substrate  14 . The reflection electrode  19  formed in the reflection display region A is not formed in the transmission display region B, either. 
   Like the color filter substrate  7 , a λ/4 layer  30  and a polarizing plate  31  are disposed in this order on a surface, on the side opposed to that provided with the TFTs  15  and the like, of the TFT substrate  2 , that is, on the side provided with a backlight as an internal light source (not shown), of the TFT substrate  2 . 
   The liquid crystal layer  8  held between the TFT substrate  2  and the color filter substrate  7  is a layer of guest-host liquid crystal. The guest-host liquid is mainly composed of nematic liquid crystal molecules having a negative dielectric anisotropy, to which a dichroic pigment is added at a specific ratio. The liquid crystal layer  8  is vertical-aligned by an alignment film (not shown). In this liquid crystal layer  8 , liquid crystal molecules are vertical-aligned with respect to the substrate when a voltage is applied thereto, and are horizontal-aligned with respect to the substrate when no voltage is applied thereto. It is to be noted that the configuration of the liquid crystal layer  8  is not limited to that described above. For example, the liquid crystal layer  8  may be made from liquid crystal molecules that are horizontal-aligned with respect to the substrate when a voltage is applied thereto and are vertical-aligned with respect to the substrate when no voltage is applied thereto. 
     FIG. 3  is a sectional view taken on line D—D′ of  FIG. 1 , which line extends in parallel to the data line  5  while passing through an approximately central portion of the date line  5 . 
   A cross-sectional structure of the liquid crystal display device of the present invention, taken on line D—D′ of  FIG. 1 , will be described with reference to FIG.  3 . 
   As shown in  FIG. 3 , in a section, adjacent to the reflection display region A, of the data line region, there are stacked the Cs line  6 , the gate insulating film  21 , the semiconductor thin film  22 , the stopper  29 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  in this order on the transparent insulating substrate  14 . It is to be noted that the gate insulating film  21  is composed of the multi-layer film having the silicon nitride film  21   a  and the silicon oxide film  21   b  and is formed so as to cover the Cs line. The data line  5  is formed on these interlayer insulating films  23  and  24 . The planarizing layer  17  and the reflection electrode  19  are stacked in this order on the data line  5 . The connection electrode  27  for connecting the drain electrode  26  to the pixel electrode  3  is formed on the data line  5  at a position corresponding to that of the Cs line  6 . A connection electrode  32  for connecting the data line  5  to the source electrode  25  is also formed on the data line  5 . 
   On the other hand, in a section, adjacent to the transmission display region B, of the data line region, the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  are removed, and the data line  5  is directly formed on the transparent insulating substrate  14 . The planarizing layer  17  and the transparent electrode  18  extending from the section, adjacent to the reflection display region A, of the data line region are stacked in this order on the data line  5  in the section, adjacent to the transmission display region B, of the data line region. 
   In this way, the section, adjacent to the transmission display region B, of the data line  5  is formed on the plane different from the plane on which the section, adjacent to the reflection display region A, of the data line  5 . Accordingly, the height of the section, adjacent to the transmission display region B, of the data line  5  is lower than the plane, adjacent to the reflection display region A, of the data line by a thickness equivalent to the total of the thicknesses of the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24 . As a result, even in the structure that the transmission display region B is made extremely close to the data line  5  for broadening the transmission display region B, it is possible to lower a difference-in-height between the transmission display region B and the data line region adjacent thereto as compared with the related art reflection-transmission hybrid type liquid crystal display device. This makes it possible to suppress enlargement of the ineffective region not satisfying the gap (thickness of the liquid crystal layer) necessary for transmission display in the section, adjacent to the data line  5 , of the transmission display region B. The liquid crystal display device  1  of the present invention is thus advantageous in minimizing enlargement of the ineffective region while broadening the transmission display region B, thereby enhancing brightness of display light in the transmission display mode as compared with the related art reflection-transmission hybrid type liquid crystal display device. 
   The present invention, which has the feature of enhancing brightness of display light in the transmission display mode as described above, may be particularly applied to a reflection-transmission hybrid type liquid crystal display device of a type putting emphasis on transmission display, more specifically, of a type specified such that the reflectance of a display panel for light is in a range of 1% or more and 10% or less, and the transmittance of the display panel for light is in a range of 5% or more and 10% or less. In this case, it is possible to obtain the largest effect of the present invention. The reflection-transmission hybrid type liquid crystal display device in which the reflectance for light and the transmittance for light are specified as described above is capable of keeping the brightness of display light in the reflection display mode at a necessary minimal level and keeping the brightness of display light in the transmission display mode at the same level as that in the transmission type liquid crystal display device, thereby improving the visibility and color repeatability. 
   The section, adjacent to the transmission display region B, of the data line  5  is preferably formed on the transparent insulating substrate  14 , that is, on the same plane of the transparent electrode  18  in the transmission display region B. With this structure, the difference-in-height between the transmission display region B and the data line region adjacent thereto can be minimized and the production process can be facilitated. 
   In the example shown in  FIG. 3 , the plane on which the section, adjacent to the transmission display region B, of the data line  5  is formed is made different from the plane on which the section, adjacent to the reflection display region A, of the data line  5  is formed by removing the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  from the transparent insulating substrate  14  in the section, adjacent to the transmission display region B, of the data line  5 . The present invention, however, is not limited thereto. For example, the plane on which the section, adjacent to the transmission display region B, of the data line  5  is formed may be made different from the plane on which the section, adjacent to the reflection display region A, of the data line  5  is formed by removing at least one of the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  in the section, adjacent to the transmission display region B, of the data line  5 . Alternatively, the plane on which the section, adjacent to the transmission display region B, of the data line  5  is formed may be made different from the plane on which the section, adjacent to the reflection display region A, of the data line  5  is formed by changing the thickness of at least one of the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  in the section, adjacent to the transmission display region B, of the data line  5  from the thickness of the at least one of the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  in the section, adjacent to the reflection display region A. 
   By the way, the section, adjacent to the transmission display region B, of the data line  5  is required to be covered with an insulating layer in order to prevent electrical contact with the transparent electrode  18 . The insulating layer covering the section, adjacent to the transmission display region B, of the data line  5  may be formed into a gentle shape, more specifically, into a normal taper shape. This is effective to suppress occurrence of liquid crystal domains, reverse tilt, and the like, and hence to prevent an inconvenience such as leakage of light. From this viewpoint, the insulating layer covering the data line  5  is preferably tilt at a rising angle of 80° or less, more preferably, 45° or less. 
   The material used for forming the insulating layer covering the section, adjacent to the transmission display region B, of the data line  5  is not particularly limited but may be an organic or inorganic material exhibiting fluidity due to heat or light such as an acrylic based material, a polyolefin based material, or a styrene based material. The insulating layer having the above-described gentle shape, that is, normal taper shape can be obtained by forming the insulating layer from the above-described material, and then making the material reflow. Alternatively, even in the case of using a material not exhibiting fluidity due to heat or light, the insulating layer having the gentle shape, that is, normal taper shape can be obtained by etching using a wet process or back etching using a dry process. Further, by using a photosensitive organic material for forming the insulating layer covering the data line  5 , the insulating layer can be highly accurately patterned at a desired position by photolithography. 
   The insulating layer covering the data line  5  may be formed by extending at least part of an irregularity forming layer portion formed in the reflection display region A. For example, in the case where the irregularity forming layer portion is made from a photosensitive organic material, the thickness of the irregularity forming layer portion covering the section, adjacent to the transmission display region B, of the data line  5  can be changed from the thickness of the irregularity forming layer portion covering the section, adjacent to the reflection display region A, of the data line  5  by adjusting the amount of exposure at the time of photolithography. With this method, since the thickness of the insulating layer on the data line  5  can be freely set, it is possible to obtain a necessary, sufficient capacitance between the electrodes and to realize the desired gentle shape. 
   The insulating layer covering the section, adjacent to the transmission display region B, of the data line  5  may be composed of only the planarizing layer  17  if the irregularity forming layer portion is composed of only the planarizing layer as shown in  FIG. 4 , the scattering layer  16  and the planarizing layer  17  if the irregularity forming layer portion is composed of the scattering layer  16  and the planarizing layer  17 , or only the scattering layer  16  if the irregularity forming layer portion is composed of only the scattering layer  16 . Alternatively, if the irregularity forming layer portion is composed of the scattering layer  16 , the planarizing layer  17 , and an additional layer, the insulating layer covering the section, adjacent to the transmission display region, of the data line  5  may be composed of the scattering layer  16 , the planarizing layer  17 , and the additional layer. 
   A method of fabricating the liquid crystal display device  1  having the structure shown in  FIGS. 1 ,  2  and  3  will be described below. 
   A gate electrode  20 , a gate insulating film  21  composed of a silicon nitride film  21   a  and a silicon oxide film  21   b , and a semiconductor thin film  22  are sequentially deposited and patterned on a transparent insulating substrate  14 . An impurity is doped in regions, on both sides of the gate electrode  20 , of the semiconductor thin film  22 , to form N +  diffusion regions. A stopper  29  is formed on the semiconductor thin film  22 , and a first interlayer insulating film  23  and a second interlayer insulating film  24  are formed in such a manner as to cover the semiconductor thin film  22  and the stopper  29 . 
   Contact holes are formed by opening both the first interlayer insulating film  23  and the second interlayer insulating film  24  at positions corresponding to those of the pair of N +  diffusion regions of the semiconductor thin film  22 , for example, by etching. It is preferable that a part of the first interlayer insulating film  23  and the second interlayer insulating film  24 , which part will be present under a section, adjacent to the transmission display region B, of a data line  5  (to be formed later) be removed by etching at the same time of the formation of the contact holes. 
   A source electrode  25  and a drain electrode  26  are formed so as to be connected to the semiconductor thin film  22  via the contact holes opened in the previous step, and are patterned into specific shapes. 
   A scattering layer  16  having a function of causing scattering reflection is formed and is patterned into a specific shape. A planarizing layer  17  is formed on the scattering layer  16 , and is patterned into a specific shape. At the time of patterning the planarizing layer  17 , portions of the gate insulating film  21 , the first interlayer insulating film  23 , and the second interlayer insulating film  24  in the transmission display region B are removed, to expose the transparent insulating substrate  14 . 
   A transparent electrode  18  made from ITO is formed by sputtering. A reflection electrode  19  is formed on the transparent electrode  18  in a region corresponding to the reflection display region A. A TFT substrate  2  including the transparent insulating substrate  14  provided with the TFTs  15  and the like is thus obtained. 
   A color filter  10  and a counter electrode  11  are formed on a transparent insulating substrate  9  in accordance with a known method, to obtain a color filter substrate  7 . 
   An alignment film is formed on each of the principal plane, provided with the TFTs  15 , of the TFT substrate  2  and the principal plane, provided with the color filter  10 , of the color filter substrate  7 . The TFT substrate  2  and the color filter substrate  7  are stuck to each other with the alignment films directed inwardly, and a gap between both the TFT substrate  2  and the color filter substrate  7  is filled with liquid crystal, to form a liquid crystal layer  8 . A λ/4 layer  30  and a polarizing plate  31  are stuck on the outer side of the TFT substrate  2 , and a λ/4 layer  12  and a polarizing plate  13  are stuck on the outer side of the color filter substrate  7 . A reflection-transmission hybrid type liquid crystal display device  1  having the same structure as that shown in  FIG. 2  is thus accomplished. 
   Although the liquid crystal display device including TFTs of the so-called bottom gate structure is used in the above-described embodiment, the present invention is not limited thereto but may be applied to a liquid crystal display device including TFTs of a top gate structure. 
   As described above, according to the present invention, there can be provided a reflection-transmission hybrid type liquid crystal device capable of ensuring a sufficient area of a transmission display region while suppressing enlargement of an ineffective region at a section, adjacent to a date line, of a transmission display region, even if the transmission display region is broadened, thereby realizing high brightness of display light in the transmission display mode. 
   While the embodiments of the present invention have been described using specific terms, such description is for illustrative purposes only, and it is to be understood that changes and variations may be made without departing from the spirit or scope of the following claims.