Abstract:
In a color liquid crystal display, a data line ( 1 ) for supplying data to pixels in accordance with an image to be displayed overlaps pixel electrodes adjacent to the pixel electrodes to which the data line is connected. Specifically, data line ( 1   g ) connected to green pixels overlaps pixels in a column direction in the alternating sequence of green and blue. Alternatively, the data line ( 1 ) may not overlap its connected pixels. The data line connected to green pixels may overlap pixels located adjacent to green pixels in a column direction in the alternating sequence of blue and red. With these arrangements, the meandering amplitude of data lines can be reduced to shorten the overall wiring length of the data lines.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a color liquid crystal display (LCD), and more particularly to a color LCD in which pixel electrodes of the same color located close to one another in a column direction are driven by a single data line. 
     2. Description of the Prior Art 
     Conventionally, an LCD having orientation control windows opened in a common electrode opposing pixel electrodes has been proposed in, for example, JPA H06-301036. An LCD having orientation control windows is a vertical orientation type LCD using liquid crystal having negative anisotropy of dielectric constant. The orientation of the liquid crystal is controlled by the curving of electric field caused between end portions of a pixel electrode and of an orientation control window. Accordingly, it is unnecessary to perform rubbing processing on orientation films to provide a pre-tilt angle. 
     3. Description of the Related Art 
     Liquid crystal located directly underneath an orientation control window is not subjected to any electric field and remains without being driven. The technique of placing a data line in such a region is proposed in Japanese Patent Application No. H10-337840 filed by the present applicant. An LCD having a data line overlapping an orientation window is described below. It is to be noted that this technique does not constitute the prior art of the present application. 
     FIG. 1 is a plan view showing a conventional LCD having a data line overlapping an orientation control window, and FIG. 2 shows a cross-sectional view taken along line A—A of FIG. 1. A plurality of gate lines  51  made of metal such as chromium are formed extending along a row direction on a transparent insulator substrate  50  composed of materials such as glass or quartz. Over this layer, although not shown in FIG. 2, thin-film transistors (TFT)  53  are formed for each pixel, and an interlayer insulating film  52  is formed covering the TFT. Over the interlayer isolation film  52 , a plurality of data lines are formed extending in columns. A source region of a TFT  53  is connected to a data line  54 . A portion of a gate line  51  constitutes a gate electrode of a TFT. A pixel electrode  56  is formed over the TFT with a planarization film  55  disposed in between. A drain region of the TFT is connected to the pixel electrode via a contact hole. A vertical orientation control film  57  is formed further on top. Provided on a substrate arranged opposing the substrate  50  are color filters  61  each colored with a primary color for image display. The primary color may be one of the three colors of red (R), green (G), and blue (B), or alternatively, cyan, magenta, and yellow. The following explanation is made using the three colors of RGB. A protective film  62  is provided over the color filters  61 , and a common electrode  63  used commonly for all pixels and an orientation control film  64  are formed over the protective film  62 . Orientation control windows  65  where no electrode is present are formed in the common electrode  63  in regions opposing pixel electrodes  56 . Liquid crystal  70  is filled between these substrates  50 , 60 . The orientation of liquid crystal molecules is controlled in accordance with the strength of electric field generated by a voltage applied between pixel electrodes  56  and the common electrode  63 . In this way, the polarizing characteristic of the liquid crystal  70  is changed, controlling the transmittance of the light linearly polarized by the polarizers  41 , 42 . 
     The liquid crystal  70  has negative anisotropy of dielectric constant. That is, the liquid crystal has the property of orienting itself in a direction perpendicular to the direction of the electric field. The orientation control films  57 , 64  are vertical orientation control films which may be made of organic materials such as polyimide and polyamide or of inorganic silane materials. Liquid crystal molecules are controlled by the orientation control films such that their initial orientation when no voltage is applied is in the direction along the line normal to the substrates. When an electric field along the length of the Figure is generated by applying a voltage between a pixel electrode  56  and the common electrode  63 , the liquid crystal located between these electrodes are tilted in a direction perpendicular to the electric field, i.e., along the width of the Figure. At the end portions of the pixel electrode  56  and of the orientation control window  65 , the electric field becomes curved, and the direction in which the liquid crystal molecules are tilted is accordingly controlled towards the orientation control window  65 . No electric field is generated in a region directly underneath the orientation control window  65  because no voltage is applied. Liquid crystal molecules are therefore not tilted and remain without being driven in this region. 
     As shown in FIG. 1, the data line  54  is formed overlapping an orientation control window in each pixel. One data line  54  is connected to and overlapped on pixels of the same color. Specifically, a data line  54   g  driving green pixels overlaps green pixels indicated by G, a data line  54   r  driving red pixels overlaps red pixels indicated by R, and a data line  54   b  driving blue pixels overlaps blue pixels indicated by B. 
     The pixel electrodes  56  are arranged in a matrix, but the pixel electrodes in one column are shifted by half a pixel away from one, another in a row direction. In addition, pixels of the same color are not located adjacent to one another. This arrangement is the so-called delta arrangement. As a data line  54  drives pixels of the same color and overlaps those pixels of the same color in positions shifted by 1.5 pixels from one another, the data line is arranged meandering by an amplitude of 1.5 pixels. 
     FIG. 3 is a plan view of a liquid crystal display having orientation control windows  66  in the shape of two letter Y&#39;s connected at their bottoms. Pixel electrodes indicated by rectangles are disposed in a delta arrangement. Each TFT  53  which includes a gate constituted by a portion of a gate line  51  extending along a row direction is formed for each pixel. The TFT is connected to the pixel electrode  56  via a contact hole. As the cross-section along A—A is identical to the cross-section of FIG.  2 , the explanation will not be repeated. 
     The data line  54  is formed overlapping an orientation control window  65  in each pixel. One data line  54  is connected to and overlapped on pixels of the same color. Specifically, a data line  54   g  driving green pixels overlaps green pixels indicated by G, a data line  54   r  driving red pixels overlaps red pixels indicated by R, and a data line  54   b  driving blue pixels overlaps blue pixels indicated by B. 
     However, when a data line  54  is formed to overlap pixels that are shifted by 1.5 pixels as described above, the wiring of the data line  54  becomes long, possibly causing the following problems. 
     With the enlargement of an area in which the data line  54  and the common electrode  63  face one another, parasitic capacitance generated between the data line and the electrode becomes larger. Consequently, time required for applying a voltage to the data line  54  (referred to as the time constant) is increased. When the time constant is larger, it may not be possible to raise the voltage on the data line  54  within a predetermined time period. Accordingly, sufficient voltage may not be applied to the pixel electrodes  56 , resulting in degradation of display quality. 
     As data lines  54  are made of metal such as chromium, a region in which a data line  54  is formed does not let light pass through. When this region is enlarged, the aperture ratio is reduced, causing a decrease in display contrast and therefore degradation of display quality. 
     By having data lines  54  meandering by an amplitude of 1.5 pixels, regions are created where two data lines  54  overlap. Margins must therefore be reserved to accommodate widths of the data lines and to maintain spaces between the data lines. This requires an increased amount of inter-pixel space and decreases aperture ratio. 
     SUMMARY OF THE INVENTION 
     In light of the above, the object of the present invention is to provide a LCD with high display quality in which the meandering amplitude of a data line is reduced, shortening the overall length of data lines. 
     According to the present invention conceived for accomplishing the above object, there is provided a color liquid crystal display comprising a plurality of pixel electrodes arranged in a matrix such that, in adjacent rows, positions of pixels associated with the same color are shifted from one another; and a data line extending in a column direction while overlapping predetermined pixel electrodes among said plurality of pixel electrodes, the data line electrically connecting to pixel electrodes associated with the same color and located closely along the column direction, while at least a portion of said data line overlaps pixel electrodes associated with a color different from the connected pixel electrodes. 
     In another aspect of the present invention, the arrangement of the pixel electrodes is a delta arrangement. 
     In a different aspect of the present invention, a row in which the data line overlaps a connected pixel electrode and an adjacent row in which the data line overlaps a pixel electrode of a different color are arranged alternately. 
     According to another aspect of the present invention, pixel electrodes on which the data line overlaps are only pixel electrodes of a different color located adjacent to the connected pixel electrodes. 
     According to a further aspect of the present invention, the color liquid crystal display comprises a common electrode provided opposing said plurality of pixel electrodes; liquid crystal sealed between said common electrode and said plurality of pixel electrodes; and an orientation controller for controlling an orientation of the liquid crystal. The liquid crystal has a negative anisotropy of dielectric constant. 
     As described above, at least a portion of the data line overlaps pixel electrodes of a different color according to the present invention. As a result, the length of the data line is shortened, and the meandering amplitude is made smaller. The time constant of the data line can therefore be reduced, achieving high display quality. 
     In the present invention, inter-pixel regions can be made smaller or pixels can be enlarged because the total area of data lines is reduced, and inter-pixel regions in which two data lines overlap no longer exist. Accordingly, the aperture ratio can be increased, accomplishing higher brightness and display quality. 
     In another aspect of the present invention, the orientation controller comprises orientation control windows including electrode openings made in the common electrode at positions corresponding to the plurality of pixel electrodes. 
     According to a different aspect of the present invention, the orientation controller comprises orientation control slopes disposed on one or both of an interface between the common electrode and the liquid crystal, and interfaces between the plurality of electrodes facing the liquid crystal, the orientation control slopes formed by causing the facing interfaces to protrude towards the liquid crystal. 
     According to a further aspect of the present invention, the orientation controller is provided within pixel regions corresponding to each of the plurality of pixel electrodes, and functions as an orientation divider for providing a plurality of discrete orientations of liquid crystal within each pixel region. According to this aspect, the data line overlaps the orientation controllers within predetermined pixel regions. 
     As described above, a predetermined data line overlaps an orientation controller. When liquid crystal with negative anisotropy of dielectric constant is employed in a vertical orientation type LCD, the orientation of the liquid crystal constantly remains unchanged from the vertical direction within regions directly above an orientation control window or an orientation control slope explained later. Such regions therefore do not contribute when displaying images. Accordingly, no decrease in aperture ratio of the overall display is caused by overlapping data lines on these regions. As no electric fields are applied to liquid crystal located directly above such orientation controller, light leakage may possibly occur when the orientation of liquid crystal in these regions is altered by other factors. However, in the present invention, while the length of data line wiring is minimized, the data lines may be formed of light-shielding materials and arranged to overlap these orientation control means, thereby also facilitating prevention of light leakage. 
     In a further different aspect of the present invention, a transistor is connected to each of the plurality of pixel electrodes, and the data line is connected via the transistors to the pixel electrodes, among the plurality of pixel electrodes, that are associated with the same color and located closely along the column direction. 
     The data line is arranged to overlap either a connected pixel electrode or a pixel electrode of a different color located adjacent thereof. Accordingly, even when the data line overlaps pixel electrodes of a color different from the associated color, the wiring between the transistor for a connected pixel electrode and the data line does not need to be made much longer and is kept to a minimal length. Operational deficiencies due to long wiring to transistors can therefore be avoided, and transistors can be reliably operated at a high speed to supply data to be displayed in each pixel from the data line to pixel electrodes via the transistors. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a schematic plan view of a color liquid crystal display according to a related art of the present invention. 
     FIG. 2 is a cross-sectional view taken along line II—II of FIG.  1 . 
     FIG. 3 is a schematic plan view of another color liquid crystal display according to a related art of the present invention. 
     FIG. 4 is a schematic plan view of a color liquid crystal display according to a first embodiment of the present invention. 
     FIG. 5 is a schematic plan view of a color liquid crystal display according to a second embodiment of the present invention. 
     FIG. 6 is a schematic plan view of a color liquid crystal display according to a third embodiment of the present invention. 
     FIG. 7 is a schematic plan view of a color liquid crystal display according to a fourth embodiment of the present invention. 
     FIG. 8 is a schematic plan view of a color liquid crystal display according to a fifth embodiment of the present invention. 
     FIG. 9 is a cross-sectional view illustrating a different structure of orientation controller for the color liquid crystal display according to the present invention. 
     FIG. 10 is a cross-sectional view illustrating a different structure of orientation controller for the color liquid crystal display according to the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 4 is a plan view showing a first embodiment of the present invention. Pixel electrodes  56  indicated by rectangles are disposed in a delta arrangement. Orientation control windows  65  are formed in the common electrode. TFTs  53  are formed for each pixel, and each TFT uses a portion of a gate line  51  extending along a row direction as a gate. Each TFT  53  is connected to a pixel electrode  56  via a contact hole. As the cross-sectional view along II—II is identical to the cross-sectional view of FIG. 2, its explanation will not be repeated here. 
     Data lines  1  extend in column directions and connect to source regions of the TFT  53 . Data line  1   g  is for driving green pixels (indicated by G), and each TFT formed for green pixels is connected to data line  1   g . In the top row in the Figure, data line  1   g  overlaps the orientation control window  65  of a green pixel. However, in the center row under the top row, data line  1   g  overlaps the orientation control window of a blue (B) pixel adjacent to a green pixel, and TFT  53  is extended to and connected with the green pixel. In the bottom row in the Figure, data line  1   g  again overlaps a green pixel. 
     Similarly, data line  1   b  is for driving blue pixels, and data line  1   r  is for driving red pixels. In the top row, these data lines overlap the pixels to which they are connected. In the next row, the data lines overlap pixels located adjacent to connected pixels, and the overlapped pixels are pixels to which the data lines are not connected. 
     According to the above arrangement, data lines  1  of the present embodiment are formed on pixels that are shifted from one another by only 0.5 pixels along the row direction. The wiring length of data lines  1  is shorter compared to data lines  54  in FIG.  1 . Moreover, the wiring length of TFT  53  does not differ by a large amount from that of FIG. 1 because, in each row, a data line  1  overlaps either a pixel which the data line drives or a pixel located adjacent thereto. 
     FIG. 5 is a plan view showing a second embodiment of the present invention. Pixel electrodes  56  indicated by rectangles are disposed in a delta arrangement. Orientation control windows  65  are formed in the common electrode. TFTs  53  are formed for each pixel, and each TFT uses a portion of a gate line  51  extending along a row direction as a gate. Each TFT  53  is connected to a pixel electrode  56  via a contact hole. As the cross-sectional view along II—II is identical to the cross-sectional view of FIG. 2, its explanation will not be repeated here. 
     Data lines  2  extend in column directions and are connected to source regions of the TFTs  53 . Data line  2   g  is for driving green pixels (indicated by G), and each TFT formed for green pixels is connected to data line  2   g . In the top row in the Figure, data line  2   g  overlaps the orientation control window  65  of a blue pixel, while, in the center row, data line  2   g  overlaps the orientation control window of a red pixel. In the bottom row of the Figure, data line  2   g  again overlaps a blue pixel. In summary, data line  2   g  does not overlap any green pixels, and all the pixels which data line  2   g  overlaps are located adjacent to a green pixel. 
     Similarly, data line  2   b  is for driving blue pixels, and data line  2   r  is for driving red pixels. These data lines overlap pixels located adjacent to connected pixels, and the overlapped pixels are pixels to which the data lines are not connected. 
     Similarly in this second embodiment, data lines  2  are formed on pixels that are shifted from one another by only 0.5 pixels along the row direction. The wiring length of data lines  2  is shorter compared to data lines  54  in FIG.  1 . Moreover, the wiring length of the TFTs  53  does not differ by a large amount from that of FIG. 1 because, in each row, a data line  2  overlaps a pixel located adjacent to a pixel which the data line drives. 
     FIG. 6 is a plan view showing a third embodiment wherein the present invention is implemented in a liquid crystal display having orientation control windows  66  in the shape of two letter Y&#39;s connected at their bottoms. Pixel electrodes  56  indicated by rectangles are disposed in a delta arrangement. TFTs  53  are formed for each pixel, and each TFT uses a portion of a gate line  51  extending along a row direction as a gate. Each TFT  53  is connected to a pixel electrode  56  via a contact hole. As the cross-sectional view along II—II is identical to the cross-sectional view of FIG. 2, its explanation will not be repeated here. 
     Data lines  3  extend in column directions and are connected to source regions of the TFT  53 . Data line  3   g  is for driving green pixels (indicated by G), and each TFT formed for green pixels is connected to data line  3   g . In the top row in the Figure, data line  3   g  overlaps the orientation control window  66  of a green pixel. However, in the center row under the top row, data line  3   g  overlaps the orientation control window of a blue (B) pixel adjacent to a green pixel. In the bottom row in the Figure, data line  3   g  again overlaps a green pixel. 
     Similarly, data line  3   b  is for driving blue pixels, and data line  3   r  is for driving red pixels. In the top row, these data lines overlap the pixels to which they are connected. In the next row, the data lines overlap pixels located adjacent to connected pixels, and the overlapped pixels are pixels to which they are not connected. 
     An orientation control window  66  in the shape of two connected letter Y&#39;s can be otherwise described as a slit created in a position corresponding to the center of the associated pixel electrode  56  and extended along the sides of the pixel poles, this slit branching at its two ends towards each of the corners of the pixel electrode  56 . A data line  3  may be formed along the shape of an orientation control window  66  by entering a pixel from its corner and exiting from another corner, similarly to the data line shown in FIG.  3 . However, it is preferable that a data line  3  be formed to enter from a side of a pixel and exit from a corner as illustrated in FIG. 6 because data line length can be reduced by such an arrangement. Pixel regions  56   a  at the top and bottom of a pixel outside the window portions branched into two are in the shape of narrow strips, and even if a data line crosses these regions, the aperture ratio is not significantly affected. 
     As data lines  3  are formed on pixels that are shifted from one another only by 0.5 pixels along the row direction, the wiring length of data lines  3  is shorter compared to conventional data lines  54 . Moreover, the wiring length of the TFTs  53  does not differ by a large amount from that of FIG. 3 because, in each row, a data line  3  overlaps either a pixel which the data line drives or a pixel located adjacent thereto. 
     FIG. 7 is a plan view showing a fourth embodiment wherein the present invention is implemented in a liquid crystal display having orientation control windows  66  in the shape of two letter Y&#39;s connected at their bottoms. Pixel electrodes  56  indicated by rectangles are disposed in a delta arrangement. TFTs  53  are formed for each pixel, and each TFT uses as a gate a portion of a gate line  51  extending along a row direction. Each TFT  53  is connected to a pixel electrode  56  via a contact hole. As the cross-sectional view along II—II is identical to the cross-sectional view of FIG. 2, its explanation will not be repeated here. 
     Data lines  4  extend in column directions and are connected to source regions of the TFTs  53 . Data line  4   g  is for driving green pixels (indicated by G), and each TFT formed for green pixels is connected to data line  4   g . In the top row in the Figure, data line  4   g  overlaps the orientation control window  66  of a blue pixel, while, in the center row, data line  4   g  overlaps the orientation control window of a red pixel. In the bottom row of the Figure, data line  4   g  again overlaps a blue pixel. In summary, data line  4   g  does not overlap any green pixels, and all the pixels which data line  4   g  overlaps are located adjacent to a green pixel. 
     Similarly, data line  4   b  is for driving blue pixels, and data line  4   r  is for driving red pixels. These data lines overlap pixels located adjacent to connected pixels, and the overlapped pixels are pixels to which they are not connected. 
     A data line  4  may be formed following the shape of an orientation control window  66  by entering a pixel from its corner and exiting from another corner, similarly to the data line shown in FIG.  3 . However, it is preferable that a data line  4  be formed to enter from a side of a pixel and exit from a corner as illustrated in FIG.  7 . 
     Similarly in this fourth embodiment, data lines  4  are formed on pixels that are shifted from one another by only 0.5 pixels along the row direction. The wiring length of data lines  4  is therefore shorter compared to conventional data lines  54 . Moreover, the wiring length of TFT  53  does not differ by a large amount from that of FIG. 3 because, in each row, a data line  4  overlaps a pixel located adjacent to a pixel which the data line drives. 
     FIG. 8 is a plan view showing a fifth embodiment wherein the present invention is implemented in a liquid crystal display having orientation control windows  67  formed from corners of pixels along their diagonals. Pixel electrodes  56  indicated by rectangles are disposed in a delta arrangement. TFTs  53  are formed for each pixel, and each TFT uses a portion of a gate line  51  extending along a row direction as a gate. Each TFT  53  is connected to a pixel electrode  56  via a contact hole. As the cross-sectional view along II—II is identical to the cross-sectional view of FIG. 2, its explanation will not be repeated here. 
     Data lines  5  extend along column directions and are connected to source regions of the associated TFT  53 . Data line  5   g  is for driving green pixels (indicated by G), and each TFT formed for green pixels is connected to data line  5   g . In the top row in the Figure, data line  5   g  overlaps the orientation control window  66  of a green pixel. However, in the center row under the top row, data line  5   g  overlaps the orientation control window of a blue (B) pixel adjacent to a green pixel. In the bottom row in the Figure, data line  5   g  again overlaps a green pixel. 
     Similarly, data line  5   b  is for driving blue pixels, and data line  5   r  is for driving red pixels. In the top row, these data lines overlap the pixels to which they are connected. In the next row, the data lines overlap pixels located adjacent to connected pixels, and the overlapped pixels are pixels to which they are not connected. 
     When orientation control windows are shaped as in the present embodiment, the meandering amplitude of a data line would be 2.5 pixels if the data line is arranged only on pixels of the same color. In this embodiment, however, data lines  5  are formed on pixels that are shifted from one another by only 0.5 pixels along the row direction. The wiring length of data lines  5  is shorter compared to data lines overlapped only on pixels of the same color. Moreover, the wiring length of the TFTs  53  does not differ by a large amount from a case where a data line is arranged only on same color pixels because, in each row, a data line  5  overlaps either a pixel which the data line drives or a pixel located adjacent thereto. 
     By practicing any of the above-described embodiments in an LCD in which data lines are formed overlapping the pixel electrodes, the data line length can be reduced compared to conventional structures because at least a portion of a data line is formed overlapping predetermined pixels adjacent to the pixels that the data line drives. Various shapes other than those described above can be used as the shape of orientation control windows, and the present invention may be implemented using any of those shapes. Although the above embodiments were explained using an LCD wherein the data lines overlap the orientation control windows, the present invention is not limited to this structure. The present invention can similarly be implemented in any LCD in which data lines are formed within pixel regions for any reasons, such as in a case where data lines are formed overlapping disclination lines constantly present within the pixels. 
     The above-described orientation control means controls the orientation of liquid crystal molecules within each pixel region of a vertical orientation type LCD using liquid crystal having negative anisotropy of dielectric constant. The orientation control means also functions as an orientation divider for dividing each pixel region into a plurality of discrete regions containing liquid crystal of different orientations. The bordering portions between different orientations within one pixel region correspond to the regions covered by the orientation control means, fixing the orientation borderline (disclination) positions within one pixel region. In the above embodiments, as a plurality of orientations of liquid crystal are provided within one pixel region, the viewing angle of the overall liquid crystal display can be improved notably. 
     In the above embodiments, data lines overlap orientation control means within predetermined pixel regions. In regions directly above an orientation control window or an orientation control slope explained below, the orientation of liquid crystal constantly remains unchanged from the vertical direction and does not contribute when displaying images. Accordingly, no decrease in aperture ratio results when data lines are overlapped in these regions. Furthermore, as no electric fields are applied to liquid crystal located directly above such orientation control means, light leakage may possibly occur when the orientation of liquid crystal in these regions is altered by other factors. However, the present invention reliably prevents light leakage by overlapping data lines made of light-shielding materials on these orientation control means. 
     Although the above embodiments employ orientation control windows formed in the common electrode as the orientation control means, the present invention is not restricted to this structure. Instead of providing an orientation control window, protruding portions  90 , 91  may be formed between the liquid crystal and the common electrode, or on the pixel electrodes on their liquid crystal sides, as shown in FIG. 9 or  10 . The slopes facing the liquid crystal created by these protruding portions  90 , 91  may be used as the orientation control means (orientation control slope). Concerning the orientation control slope, refer, for example, to Japanese Patent Application No. H10-337840 filed by the present applicant. FIGS. 9 and 10 correspond to the schematic cross-sectional view along II—II of FIGS. 4-8, and the structures that correspond to those shown in FIG. 2 are indicated by corresponding reference numerals. In the example shown in FIG. 9, protruding portions  90  made of an insulating material are formed in patterns similar to the orientation control windows  65 , 66  of FIGS. 4 and 6 between the liquid crystal and the common electrode  63  (i.e. on a surface of the orientation film  64  facing the liquid crystal layer  70 , since the orientation film  64  covers the common electrode  63 ). According to FIG. 10, protruding portions  91  made of an insulating material are created in patterns similar to the orientation control windows of FIGS. 4 and 6 underneath a plurality of pixel electrodes  56  formed in a matrix pattern on a first substrate  50 . In the example of FIG. 10, the shape of the protruding portion  91  is reflected in the pixel electrode  56  and the orientation film  57 . The surface of the orientation film  57  therefore protrudes towards the liquid crystal. 
     By providing such protruding portions  90 , 91 , the electric field applied to the liquid crystal  70  becomes curved as indicated by dotted lines in FIGS. 9 and 10. Orientation of liquid crystal  70  is therefore separately controlled on both sides of the protruding portions  90 , 91 , with the protruding portions  90 , 91  functioning as the orientation control slopes. The present invention can reduce data line wiring and achieve a high quality liquid crystal display device similarly to the above embodiments while arranging data lines  1  (2,5) to spatially overlap with these protruding portions  90 , 91 . 
     The above embodiments were described using, as an example, the so-called delta arrangement in which pixels of the same color in the column direction are shifted from one another by 1.5 pixels along a row direction. However, the shift amount is not limited to 1.5 pixels. Except when using a stripe arrangement wherein pixels of the same color are aligned along a straight line in the column direction, the present invention is similarly effective when, for example, the pixels are arranged shifted by 1.2 pixels.