PATENT ABSTRACT
An In Plane Switching (IPS) liquid crystal displaying apparatus includes a TFT array substrate, an opposite substrate opposed to the TFT array substrate and a liquid crystal interposed between the TFT array substrate and the opposite substrate. The TFT array substrate includes a plurality of driving electrodes formed on a passivation film and connected with the plurality of TFTs, a plurality of opposite electrodes formed on the passivation film, each of the plurality of opposite electrodes opposing the respective plurality of driving electrodes, and a plurality of common lines configured to connect each of the plurality of opposite electrodes with each of a plurality of pixels. The TFT array substrate provided with a light shielding formed in such a manner as to superpose one signal line of the plurality of signal lines and one opposite electrode of the plurality of opposite electrodes.

PATENT DESCRIPTION
This application is based upon and claims the benefit of priority under 35 U.S.C. § 120 for U.S. application Ser. No. 10/733,364, filed Dec. 12, 2003, U.S. application Ser. No. 10/200,762, filed Jul. 24, 2002, and U.S. application Ser. No. 09/110,076, filed Jul. 2, 1998, and under 35 U.S.C. § 119 from Japanese Patent Application 09-283834, filed Oct. 16, 1997, the entire contents of each of which are incorporated herein by reference. 

   BACKGROUND OF THE INVENTION 
   The present invention relates to an IPS In Plane Switching liquid crystal displaying apparatus by generating an electric field parallel to an array substrate to drive the liquid crystal. More particularly, the present invention relates to a construction of a highly bright liquid crystal displaying apparatus increased in aperture ratio by reducing influences of the leakage of electric field from a signal line, thereby reducing the light shielding area. 
   DISCUSSION OF THE BACKGROUND 
   In an active matrix type liquid crystal displaying apparatus, an IPS system where the direction of the electric field to be applied on the liquid crystal is made parallel to the array substrate is mainly used as a method of obtaining a wider viewing angle (for example, see Japanese Unexamined Patent Publication No. 254712/1996). It is reported that this system removes almost all of the change in the contrast and the inversion of the gradation level in changing the viewing-angle direction (see, for example, AsiaDisplay,  95 , page, 577 to 580 by M. Oh-e, and others). 
   A construction of one pixel of the conventional IPS liquid crystal displaying apparatus is depicted in  FIGS. 43   a  and  43   b .  FIG. 43   a  is the plain view thereof.  FIG. 43   b  is a sectional view taken along a line A-A of  FIG. 43   a .  FIG. 44  is a circuit diagram showing an equivalent circuit of one pixel of the pixel electrode of an IPS liquid crystal displaying apparatus.  FIG. 45  is a circuit diagram for illustrating the circuit of the IPS liquid crystal displaying apparatus. Referring to  FIGS. 43   a  and  43   b , reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a thin film transistor (TFT), numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  12  denotes a BM (black matrix), numeral  14  denotes a contact hole, numeral  15  denotes a source electrode, and numeral  16  denotes a drain electrode. Numeral  20  denotes an array substrate comprising glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  denotes an opposite substrate arranged opposite to the array substrate  20 . Numeral  40  denotes a slit which is a gap between the signal line  3  and the opposite electrode  6 , and numeral  50  denotes an opening. Referring to  FIG. 44  and  FIG. 45 , the same reference numerals as those of  FIGS. 43   a  and  43   b  depict the same parts or its equivalents as those of  FIGS. 43   a  and  43   b.    
   The construction and operation of the conventional IPS liquid crystal displaying apparatus will be described according to  FIGS. 43   a  and  43   b ,  FIG. 44  and  FIG. 45 . Referring to  FIG. 45 , a plurality of grid shaped pixels encircled by the scanning line  2  and the signal line  3  can be made by crossing, at an approximately right angle between a scanning line  2  connecting the scanning line driving circuit  102  and a signal line  3  connecting the signal line driving circuit  101 . A TFT (Thin Film Transistor) is provided at each intersection point between a signal line and a scanning line for forming the grid shaped pixel. Numeral  103  denotes a circuit for common lines. 
   This condition is shown by an equivalent circuit in  FIG. 44 . The TFT  4  is a semiconductor element having three electrodes of a gate electrode, a source electrode  15  and a drain electrode  16 . The gate electrode is connected with a scanning line  2  extended from the scanning line driving circuit. The source electrode  15  is connected with the signal line  3  connected with the signal line driving circuit. The remaining drain electrode  16 , connected with the driving electrode  5 , drives the liquid crystal by an electric field caused between the driving electrode  5  and the opposite electrode  6 . Numeral  7  denotes a storage capacitor for storing the electric charge between the driving electrode  5  and the opposite electrode  6 . The construction of one pixel will be described in accordance with  FIG. 43   a  and  FIG. 43   b . In a pixel formed through the crossing between the scanning line  2  and the signal line  3  are provided a driving electrode  5  for driving the liquid crystal layer, an opposite electrode  6  and a TFT  4 . In the TFT  4  there are three electrodes. The scanning line  2  connected with the scanning line driving circuit shown in  FIG. 45  is connected with the gate electrode of the TFT  4 , so as to apply the scanning signal, the scanning line driving circuit outputs, upon the gate electrode of the TFT  4 . 
   The signal line  3  connected with the signal line driving circuit is connected with the source electrode  15  of the TFT  4  to transmit the image signal the signal line driving circuit outputs. The drain electrode  16  of the TFT  4  is connected with the driving electrode  5  through a contact hole  14  as shown in  FIG. 43   a . In the same pixel, an opposite electrode  6  is provided to be engaged face to face with the driving electrode  5 . The opposite electrode  6  is connected with the common line  8 . The common line  8  is connected with each opposite electrode  6  provided in each pixel on the TFT array substrate  20 . 
   The sectional construction of the picture section will be described in accordance with  FIG. 43   b . A driving electrode  5  and an opposite electrode  6  are respectively formed on the glass substrate  1 . Although not shown in  FIG. 43   b , the scanning line  2  and the common line  8  are also formed in the same layer as that of the driving electrode  5  and the opposite electrode  6 . The gate insulating film  9  is laminated on a glass substrate by covering the driving electrode, the opposite electrode, the scanning line and the common line, and the signal line  3  is formed on the gate insulating film  9 . Although not shown in  FIG. 43   b , the storage capacitor forming electrode  7  is also formed in the same layer as that of the signal line  3 . A passivation film  10  is laminated further on the signal line  3 , so as to form the TFT array substrate  20 . The TFT array substrate  20  and the opposite substrate  30  is superposed. The IPS liquid crystal displaying apparatus is made with a liquid crystal  11  being sealed between the TFT array substrate  20  and the opposite substrate  30 . 
   The IPS liquid crystal displaying apparatus is a system where the electric filed field is caused along the surface of the TFT array substrate  20  between the driving electrode  5  and the opposite electrode  6  provided on the TFT array substrate  20 . Thus, the opposite substrate  30  is a no-electrode substrate having no electrode. On the opposite substrate  30  there is provided a BM  12  which is a light shielding film. Although not shown, the light leaked from a slit  40  of  FIG. 43   a  is to be shielded with a back light, provided on the under side of the TFT array substrate, as a light source in  FIG. 43   b.    
   An area surrounded by broken lines shown by  50 , defining an opening per pixel, functions as a role of a window through which light passes with the back light as a light source. But the light from the back light is shielded by a driving electrode  5 , an opposite electrode  6 , a black matrix  12  and so on, thereby influencing upon the picture quality of the liquid crystal display. Thus, a problem is to reduce the ratio, in area, of the driving electrode  5 , the opposite electrode  6 , the black matrix  12  and so on to be occupied in the area of the opening  50 . 
   The above description is given about the construction of the pixel of the conventional IPS liquid crystal displaying apparatus about  FIGS. 43   a  and  43   b ,  FIG. 44  and  FIG. 45 . The operation of the IPS liquid crystal displaying apparatus will be described. The gate electrode is provided in each pixel. The gate electrode of the TFT is connected with the scanning line  2 . The source electrode  15  is connected with the signal line  3 . 
   The drain electrode  16  is connected with the driving electrode  5 . Such a TFT  4  is a semiconductor switching element, which controls the driving operation of the liquid crystal of each pixel. When a scanning signal is applied, through the scanning line  2  from the scanning line driving circuit, upon the gate electrode of the TFT  4 , all the TFT  4  of this horizontal line is respectively switched on. 
   When the gate electrode is switched on, the image signal transmitted from the signal line driving circuit flows to the drain electrode  16  by way of the source electrode  15  and is stored in the driving electrode  5  connected with the drain electrode  16 . Electric charge applied in the driving electrode  5  is stored with respect to the opposite electrode  6  and the gate electrode is turned on again. The electric charge of that time is stored before the new image signal electric charge is applied. The driving electrode  5  and the opposite electrode  6  function as a capacitor in that the electric charge is stored while the gate electrode is on, and the stored electric charge is held as it is when the gate electrode is turned off. The storage capacitance  13  shown in  FIG. 44  increases the accumulating force of the capacitance. The storage capacitance  13  is formed by the vertical lamination of the storage capacitance electrode  7  and the common line  8  through the gate insulating film  9 . 
   In the conventional IPS liquid crystal displaying apparatus shown in  FIGS. 43   a  and  43   b , between the signal line  3  provided in the side end portion of one pixel and the opposite electrode  6  formed in parallel to the signal line  3  is caused an electric field due to the potential difference between the signal line  3  and the opposite electrode  6 .  FIG. 46  is a view showing influences to be applied, upon the electric field to be caused between the driving electrode  5  and the opposite electrode  6 , by the electric field caused between the signal line  3  and the opposite electrode  6  of the conventional IPS liquid crystal displaying apparatus, which has the TFT array substrate where the driving electrode  5  and the opposite electrode  6  are formed in the layer lower than the signal line  3 . In  FIG. 46 , changes in the potential caused between the driving electrode  5  and the opposite electrode  6  is obtained as a simulator. 
   In  FIG. 46 , the electric potential in the window upper portion or lower portion is calculated when a white window has been displayed in the half tone of the relative transmission factor 50%. 
   It is desirable to correctly drive the liquid crystal to have the driving electrode  5  between two opposite electrodes  6  so that the potential distribution is symmetrical around the driving electrode  5 . It is found out from  FIG. 46  that the potential distribution of an area near the signal line  3  of the opening  50  is subjected to the influences of the leakage of electric field caused between the signal line  3  and the opposite electrode  6 , thus resulting in asymmetric potential distribution. The electric field is caused along the surface of the glass substrate  1 , thus causing a problem like crosstalk. For example, when a white window is displayed in such black displaying as shown in  FIG. 47 , there prises a problem on the display called “longitudinal crosstalk” where the vertical luminance of the window portion changes with respect to the other black displaying portion. 
   An example in a case of a normally black mode (wherein the displaying becomes black with the voltage being not applied) will be described in  FIG. 44 . When such a window pattern in  FIG. 47  is displayed, the same voltage as that of the opposite electrode  6  is applied during the selecting period of the black displaying portion  111  upon the signal line  3  of the pixels of the window and its upper and lower portions during the picture face, and a voltage necessary to the white displaying  113  is applied during the selecting period of the white displaying portion  111 . 
   The voltage of a value where the absolute value of the electric potential value between the electrodes has been averaged by hour is applied upon the liquid crystal  11  effectively. Therefore, for example, when the black displaying and the white displaying are equal in the selecting period, the effective potential equal to the half tone display  112  is applied upon these pixels between the signal line  3  and the opposite electrode  6 . At this time, the liquid crystal on the slit  40  between the signal line  3  and the opposite electrode  6  becomes a transmission mode by the electric field to horizontal to the glass substrate  1  to be caused between the signal line  3  and the opposite electrode  6 . The electric field to be caused by the electrical potential difference between the signal line  3  and the opposite electrode  6  gives influences even upon the electric field between the driving electrode  5  and the opposite electrode  6 , so as to change the liquid crystal of the black displaying portion into the transmission mode. As a result, the crosstalk is caused. 
   In order to prevent such longitudinal crosstalk from being caused, the leaking light transmitting through the slit  40  between the signal line  3  and the opposite electrode  6  is required to be shielded by the BM  12  formed on the opposite substrate  30  and to prevent the electric field, caused between the signal line  3  and the opposite electrode  6 , from being interfered with the electric field between the driving electrode  5  and the opposite electrode  6  with the driving electrode  5  and the opposite electrode  6  spaced apart from the opposite electrode  6  of the side end portion on the side of the opening  50 , and the signal line  3 . When the driving electrode  5  and the opposite electrode  6  are separated from the signal line  3  to make larger the width of the opposite electrode  6  adjacent to the signal line  3 , and the aperture ratio of the opening  50 , namely, a portion to be occupied by an area where the area of the driving electrode  5  and the opposite electrode  6  and so on is subtracted from the area of the opening  50  with respect to the area of the opening  50  surrounded with broken lines in  FIG. 43   a , becomes smaller to make the picture quality worse. In order to develop the high picture quality liquid crystal displaying apparatus, it is necessary to shield the light, without reducing the aperture ratio, the electric field to be caused between the signal line  3  and the opposite electrode  6  adjacent to the signal line  3 . 
   As clear from  FIG. 43   b , level of the surface of the passivation film  10  which is an upper layer film of the array substrate  20  is not flat (level difference), and the gap between the surface of the passivation film  10  and the opposite substrate  30  is not flat. Thus, uneven luminance is likely to be caused, causing the picture quality to worsen. The level difference provided makes not only the array substrate inferior due to crack, but also disconnects the wiring on the array substrate due to the level difference portion in the manufacturing operation with a problem in improving the yield factor and reliability of the product. 
   Further, in accordance with the conventional IPS liquid crystal displaying apparatus, picture quality is deteriorated by light leaking transmitted from the slit  40 , the light being emitted by a back light serving as a light source. In order to shield the leaked light, the black matrix  12  is provided on the opposite substrate  30 . However, when the TFT array substrate  20  is superposed with the opposite substrate  30 , there might be generated error. Then, the black matrix  12  has been formed in such a manner as to be somewhat larger with some margin for the purpose of taking the error into consideration. However, there arises such a problem in which opening ratio is lowered when shieding effect is enhanced by making the black matrix  12  large. 
   SUMMARY OF THE INVENTION 
   The first object of the present invention is to solve the problems mentioned above, and to provide an IPS liquid crystal displaying apparatus causing electric field parallel to a glass substrate, the IPS liquid crystal displaying apparatus capable of improving shielding effect against electric field leaking from the signal line, making the opening wide (that is, making opening ratio high) by lowering the light shielding area. Further, the second object of the present invention is to provide a high quality IPS liquid crystal displaying apparatus in which cost for producing the apparatus is decreased by preventing the lines from disconnection thereby improving the yield factor. 
   The IPS liquid crystal displaying apparatus of the present invention comprises: 
   a TFT array substrate, 
   an opposite substrate opposed to the TFT array substrate and 
   liquid crystal interposed between the TFT array substrate and the opposite substrate, 
   wherein the TFT array substrate is composed of a glass substrate, a gate insulating film formed on the glass substrate, a passivation film formed on the gate insulating film, a plurality of scanning lines for transmitting a scanning signal, the plurality of scanning lines being formed on the glass substrate, a plurality of signal lines for transmitting an image signal, the plurality of signal lines being formed on the gate insulating film, a plurality of pixels arranged in grid like pattern by crossing the plurality of scanning lines with the plurality of signal lines, a plurality of TFTs implementing switching operation of the image signal on the basis of the scanning signals, a plurality of driving electrodes connected with the TFT, a plurality of opposite electrodes arranged in such a manner that each of the plurality of opposite electrodes is opposed to each of the driving electrodes, and a plurality of common lines for mutually connecting each of the opposite electrode of one of the plurality of pixels with the other one of the plurality of pixels, 
   wherein the TFT array substrate is formed on the passivation film, the passivation film being different from a layer provided with the driving electrode and the opposite electrode. 
   The IPS liquid crystal displaying apparatus of the present invention is provided with a driving electrode for driving the liquid crystal layer by causing the electric field parallel to the TFT array substrate face, the driving electrode being connected with the TFT, and an opposite electrode connected with a common line. At least the opposite electrode has a TFT array substrate formed on the passivation film, different from a layer where the signal line is formed. 
   The IPS liquid crystal displaying apparatus of the present invention has a TFT array substrate having an opposite electrode formed to cover one portion of the signal line or all the portion of the signal line. 
   The IPS liquid crystal displaying apparatus of the present invention has a TFT array substrate having an opposite electrode formed to cover one portion of the scanning line or all the portion thereof, having at least an opposite electrode in a layer different from the scanning line. 
   The IPS displaying apparatus of the present invention has a common line and a scanning line on the same layer, and a signal line provided on the gate insulating film. 
   The IPS liquid crystal displaying apparatus of the present invention has a TFT array substrate with the surface of the passivation film being approximately flat in shape. 
   The IPS liquid crystal displaying apparatus of the present invention has a light shielding means formed to have the signal line and the opposite electrode superposed. 
   The IPS displaying apparatus of the present invention has a TFT array substrate formed, to have for superposition in different layers, a TFT for switching the picture image signal in accordance with the scanning signal, a driving electrode for accumulating, while the switch of the TFT is off, the electric load stored when the switch of the TFT is on, and a storage capacitance increasing electrode for reinforcing the capacitance of the driving electrode. 

   
     BRIEF EXPLANATION OF THE DRAWINGS 
       FIG. 1  is a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 1 of the present invention; 
       FIG. 2  is a plain view showing the construction of one pixel of an IPS switching type liquid crystal displaying apparatus of Embodiment 1 of the present invention; 
       FIGS. 3   a  and  3   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of the embodiment 1 of the present invention; 
       FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b  depict is a process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 1 of the present invention; 
       FIGS. 9   a ,  9   b ,  10   a ,  10   b ,  11   a ,  11   b ,  12   a ,  12   b ,  13   a  and  13   b  depict is another process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 1 of the present invention; 
       FIGS. 14   a ,  14   b ,  15   a ,  15   b ,  16   a ,  16   b ,  17   a ,  17   b ,  18   a  and  18   b  depict is a still another process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 1 of the present invention; 
       FIGS. 19   a  and  19   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 2 of the present invention; 
       FIGS. 20   a ,  20   b ,  21   a ,  21   b ,  22   a ,  22   b ,  23   a ,  23   b ,  24   a  and  24   b  depict a process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 2 of the present invention; 
       FIGS. 25   a  and  25   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 3 of the present invention; 
       FIGS. 26   a ,  26   b ,  27   a ,  27   b ,  28   a ,  28   b ,  29   a ,  29   b ,  30   a  and  30   b  depict a process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 3 of the present invention; 
       FIGS. 31   a  and  31   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 4 of the present invention; 
       FIGS. 32   a  and  32   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 5 of the present invention; 
       FIG. 33  is a view showing the potential distribution when the driving electrode and the opposite electrode are in a layer higher than the upper layer; 
       FIGS. 34   a  and  34   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 6 of the present invention; 
       FIGS. 35   a  and  35   b  are a plain view and a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 7 of the present invention; 
       FIG. 36  is a sectional view showing the construction of one pixel of an IPS liquid crystal displaying apparatus of Embodiment 8 of the present invention; 
       FIGS. 37   a ,  37   b ,  38   a ,  38   b ,  39   a ,  39   b ,  40   a ,  40   b ,  41   a ,  41   b ,  42   a  and  42   b  depict a process flow of a TFT array substrate of an IPS liquid crystal displaying apparatus of Embodiment 9 of the present invention; 
       FIGS. 43   a  and  43   b  are a plain view and a sectional view showing the construction of one pixel of the conventional IPS liquid crystal displaying apparatus; 
       FIG. 44  shows an equivalent circuit of one pixel of the conventional IPS liquid crystal displaying apparatus; 
       FIG. 45  is a block diagram showing the construction of the conventional IPS liquid crystal displaying apparatus; 
       FIG. 46  is an explanatory view showing the electric potential distribution when the driving electrode and the opposite electrode are in a layer lower than the signal line; and 
       FIG. 47  an explanatory a view showing a crosstalk. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Embodiment 1 
   One embodiment of the present invention will be described in accordance with drawings. The reference numerals in Embodiment 1 are the same as those of the conventional reference numerals.  FIG. 1  is a sectional view showing the construction of one pixel of the IPS type liquid crystal displaying apparatus in Embodiment 1 of the present invention.  FIG. 2  is its plain view.  FIG. 1  is a sectional view taken along a line of A-A in  FIG. 2 . Referring to the drawing, reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a TFT, numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes a common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  12  denotes a BM, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of the transistor, and numeral  16  denotes a drain electrode of the transistor. Numeral  20  denotes an array substrate comprising a glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  denotes an opposite substrate cerving as a displaying picture face arranged opposite to the array substrate  20 . Numeral  40  denotes a slit which is a gap between the signal line  3  and the opposite electrode  6 . Numeral  50  denotes an opening of a pixel.  FIG. 3  depicts the construction of one pixel of the IPS type liquid crystal displaying apparatus when a channel passivation TFT  21  which is one type of a TFT  4  is provided as a TFT to be used in the IPS type liquid crystal displaying apparatus shown in  FIG. 2 .  FIG. 3   a  is its plain view.  FIG. 3   b  is a sectional view. 
   The construction of the pixel of the IPS type liquid crystal displaying apparatus will be described in accordance with  FIG. 1  and  FIG. 2 . Referring to the drawings, numeral  1  denotes a glass substrate with a scanning line  2  being formed on the glass substrate  1 . A gate insulating film  9  is laminated to cover the scanning line  2  and a signal line  3  is provided on the gate insulating film  9 . A passivation film  10  is laminated on the signal line  3 . A driving electrode  5  and an opposite electrode  6  are provided on the passivation film  10 . The TFT array substrate  20  is made as described above. A substrate  30  which is provided to be opposed to the TFT array substrate  20  is an opposite substrate for grasping a liquid crystal  11  with respect to the TFT array substrate  20 . The IPS liquid crystal displaying apparatus of the present invention causes an electric field along the surface of the TFT array substrate, and thereby to drive the liquid crystal  11  by controlling the direction of the electric field. 
     FIG. 2  is a plain view of an IPS liquid crystal displaying apparatus shown in  FIG. 1 . Referring to FIG.  2 , numeral  2  denotes a scanning line and numeral  3  denotes a signal line. An area surrounded by the scanning line  2  and the signal line  3  becomes one pixel. Numeral  4  denotes a TFT provided in the intersection point between the scanning line  2  and the signal line  3 . The gate electrode of three electrodes having the TFT  4  is connected with the scanning line  2 , and the source electrode  15  is connected with the signal line  3 . The drain electrode  16  of three electrodes having the TFT  4  is connected with the driving electrode  5  by a contact hole  14  in an upper layer through a passivation film  10  (not shown). An opposite electrode  6  which is provided opposite to be engaged with the driving electrode  5  is connected with the common line  8  of the same layer. The common line  8  not shown is connected with the opposite electrode  6  of the other adjacent pixel. The driving electrode  5 , the opposite electrode  6 , and the common line  8  are formed at the same time in a layer upper than the signal line  3 . 
   Numeral  7  denotes storage capacitance for keeping the potential of the driving electrode  5 . The opposite electrode  6  and the drain electrode  16  are laminated vertically. Numeral  40  denotes a slit between the signal line  3  and the opposite electrode  6 . The BM  12  provided in the opposite substrate  30  shown in  FIG. 1  shields the leakage light which transmits through the slit  40  with the back light as a light source. Numeral  50  denotes an opening. The larger the area of the opening becomes, the higher picture quality the liquid display can obtain. As the IPS liquid crystal displaying apparatus retains the electric charge stored in the driving electrode  5  connected with the drain electrode  16  of the TFT  4  and drives the liquid crystal  11  by causing the electric field along the surface of the glass substrate  1 , the opposite substrate  30  is a no-electrode substrate not provided with an electrode. One example of the process flow of the TFT array substrate for composing the pixel of the IPS liquid crystal displaying apparatus in Embodiment 1 will be described. 
     FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b  depict a process flow of a TFT array substrate.  FIGS. 9   a ,  9   b ,  10   a ,  10   b ,  11   a ,  11   b ,  12   a ,  12   b ,  13   a  and  13   b  depict another process flow of a TFT array substrate.  FIGS. 14   a ,  14   b ,  15   a ,  15   b ,  16   a ,  16   b ,  17   a ,  17   b ,  18   a  and  18   b  depict still another process flow of a TFT array substrate. The left-hand side views of  FIG. 4   a  through  FIG. 18   a  show the TFT array substrate and the right-hand side views thereof show the terminal portions for embodying the scanning line  2  into the scanning line driving circuit. Referring to  FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b  a step  1  ( FIGS. 4   a  and  4   b ) forms a scanning line  2 , of approximately 50 nm through 800 nm in film thickness, under the construction of any one of Cr, Al, Mo, Ta, Cu, Al—Cu, Al—Si—Cu, Ti, W, or of their alloy, or transparent materials such as ITO (Indium Tin Oxide) or the like or the laminated thereof. The scanning line  2  functions even as the gate electrode of the TFT  4 . As an etching method in forming the scanning line  2  may be used an etching method as the section becomes rectangular although the taper etching which becomes trapezoidal in section is shown in  FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b.    
   In step  2  ( FIGS. 5   a  and  5   b ), a gate insulating film  9  is accumulated to cover the scanning line  2 , amorphous silicon with impurities such as amorphous silicon, phosphorus and so on being doped in it is continuously accommodated, then amorphous silicon is patterned and the TFT  4  is formed with a channel etch type. A gate insulating film  9  is proper to have approximately 200 nm through 600 nm in thickness by using a transparent insulating film such as silicon nitride, silicon oxide or the like, film oxide of a gate electrode material (namely, a material of the scanning line  2 ) or their laminated films. Also, a micro crystal silicon with impurities such as phosphorus or the like being doped in it can be used as a material instead of amorphous silicon with impurities such as phosphorus or the like being doped in it. 
   In step  3  ( FIGS. 6   a  and  6   b ) there is formed a signal line  3  simultaneously with a source electrode  15  and a drain electrode  16  of the TFT  4 . The signal line  3  functions as a source electrode  15 . The signal line  3  is formed of any one of Cr, Al, Mo, Ta, Cu, Al—Cu, Al—Si—Cu, Ti, W or alloy mainly made of them, or alloy made chiefly of them, or a transparent material of such as ITO or the like or their laminated construction. 
   In step  4  ( FIGS. 7   a  and  7   b ) there is formed a passivation film  10  with a transparent insulating film of silicon nitride, silicon oxide and so on. In order to electrically connect the driving electrode  5  with the drain electrode  16 , the partial passivation film on the drain electrode  16  of the TFT  4  is removed to form a contact hole  14 . At this time, the gate insulating film  9  and the passivation film  10  are removed from the terminal portion of the scanning line  2  at the same time and the passivation film  10  is removed from the terminal portion of the signal line  3  so that the external terminal, the scanning line  2  and the signal line  3  can be connected electrically. 
   In step  5  ( FIGS. 8   a  and  8   b ) there is formed the driving electrode  5  and the opposite electrode  6 , as an electrode for forming the electric field in a horizontal direction to the substrate face, with any one of Cr, Al, Mo, Ta, Cu, Al—Cu, Al—Si—Cu, Ti, W or alloy mainly composed of at least two thereof, or a transparent material of such as ITO or the like or their laminated construction or their laminated construction including them. The driving electrode  5  is connected with the drain electrode  16  through the contact hole  14 . The opposite electrode  6  is connected with the common line  8 . The opposite electrodes  6  are superposed through the drain electrode  16  and the passivation film  10  to form the storage capacitance  7  for keeping the electric potential of the driving electrode. By the above five steps, the driving electrode  5  and the opposite electrode  6  are provided in the layer (namely, on the side of the opposite substrate  30 ) upper than the signal line  3 . The TFT array substrate  20  which can apply the horizontal electric field to the substrate face can be made by using a channel etch type TFT with five photo-lithography processes. 
   Although the terminal  22  is formed by using the metal of the same layer as that of the scanning line  2  in the process flow of the above described TFT array substrate, a terminal can be formed by using the ITO. The ITO has only to be made of the same layer as that of the scanning line or the signal line  3 . Although the signal wiring has been straightly etched, it is desirable to conduct a taper etching operation. When the signal line is formed on Cr under the Al laminated construction, an over etching operation is conducted in Cr when the Cr has been patterned after the Al is patterned, the construction becomes protective in construction, causing disconnection. In order to prevent it, the etching of Al is conducted again after the patterning of the Cr. Retreat the Al from the Cr end face and the protecting construction can be prevented. This etching of the Al can use the taper etching. This method can be adapted when the signal line is formed under the laminated construction of different metals of two types or more of any one of Cr, Al, Mo, Ta, Cu, Al—Cu, Al—Si—Cu, Ti, W or alloy mainly composed of at least two thereof, or transparent materials such as ITO or their laminated construction. 
   In  FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b  the driving electrode  5  and the opposite electrode  6  can be formed on the same layer and the driving electrode  5  and the signal line  3  are formed at the same time as shown in  FIGS. 9   a ,  9   b ,  10   a ,  10   b ,  11   a ,  11   b ,  12   a ,  12   b ,  13   a  and  13   b . After forming the passivation film  10  by using the silicon nitride or the like, the opposite electrode  6  can be formed. In this case, the driving electrode  5  and the opposite electrode  6  are formed in a separate layer. A channel passivation film transistor  21  which is one type of TFT  4  can be used, instead of a TFT used for the TFT array substrate shown in  FIGS. 4   a ,  4   b ,  5   a ,  5   b ,  6   a ,  6   b ,  7   a ,  7   b ,  8   a  and  8   b .  FIGS. 14   a ,  14   b ,  15   a ,  15   b ,  16   a ,  16   b ,  17   a ,  17   b ,  18   a  and  18   b  are views showing a process flow of the TFT array substrate formed by using a channel passivation film transistor  21 . 
   The TFT array substrate shown in  FIGS. 14   a ,  14   b ,  15   a ,  15   b ,  16   a ,  16   b ,  17   a ,  17   b ,  18   a  and  18   b  includes a pixel of the IPS liquid crystal displaying apparatus shown in  FIG. 3 , and is formed much more in branch layer than the TFT array substrate shown in  FIG. 5 . This is due to the difference of a producing step ( FIGS. 15   a  and  15   b ) of forming a scanning line  2 , then successively depositing the gate insulating film  9 , the amorphous silicon  9   b , and the channel passivation film to cover the scanning line  2 , then forming the channel passivation film  21 , ion-injecting the impurities such as P and so on into the amorphous silicon with the channel passivation film  21  as a mask to form an n-layer, and forming the channel passivation film transistor. 
   In the characteristic construction of the TFT array substrate  20  of the IPS liquid crystal displaying apparatus of Embodiment 1, the driving electrode  5  and the opposite electrode  6  on the array substrate  20  are arranged on a layer (namely, on the side of the opposite substrate  30 ) upper than the signal line  3 . This arrangement allows a step of forming the contact hole  14  and removing the passivation film  10  from the terminal portion of the signal line  3 , and a step of removing the insulating film  9  and the passivation film  10  from the terminal portion of the scanning line  2  to carry out at one time. Thus, the number of the masks can be reduced by one and thereby the manufacturing cost can be reduced. 
   It has been found by forming the driving electrode  5  and the opposite electrode  6  on the layer of the side of the opposite substrate  30  with the signal line  3  and the layer being made different that the influences of the electric field caused by the electric potential difference between the opposite electrode  6 , provided adjacently to the signal line  3  on the end portion of the opening  50  shown in  FIG. 2 , and the signal line  3 , as judged from the description to be mentioned later in Embodiment 5. Thus, the opposite electrode of the side end portion of the opening  50  can be made closer to the signal line  3  and the area of the opening  50  can be made larger. 
   In  FIG. 1 , the driving electrode  5  and the opposite electrode  6  are directly in contact with the liquid crystal interposed between the TFT array substrate  20  and the opposite substrate  30 , so that the liquid crystal can be efficiently driven, and the space between the driving electrode  5  and the opposite electrode  6  can be made wider. Thus, an effect of improving the aperture ratio can be obtained. 
   Embodiment 2 
     FIGS. 19   a  and  19   b  show the construction of the pixel electrode of the liquid crystal displaying apparatus of the embodiment 2 of the present invention.  FIG. 19   a  is its plain view.  FIG. 19   b  is a sectional view taken along a line of A-A of  FIG. 19   a .  FIGS. 20   a ,  20   b ,  21   a ,  21   b ,  22   a ,  22   b ,  23   a ,  23   b ,  24   a  and  24   b  are views showing the process flow of the array substrate. Referring to the drawing, reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a thin film transistor (TFT), numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  12  denotes a BM, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of a transistor, and numeral  16  denotes a drain electrode. Numeral  18  denotes a through-hole, numeral  20  denotes an array substrate comprising a glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  denotes an opposite substrate serving as a display picture face arranged opposite to the array substrate  20 . Numeral  40  denotes a slit which is a gap between the signal line  3  and the opposite electrode  6 . Numeral  50  denotes an opening of the pixel. 
   In Embodiment 1, the common line  8  is formed on the same layer as that of the opposite electrode  6 . In the embodiment 2, the common line  8  is formed on the same layer as that of the scanning line  2 , namely, on the glass substrate  1  as shown in  FIGS. 20   a ,  20   b ,  21   a ,  21   b ,  22   a ,  22   b ,  23   a ,  23   b ,  24   a  and  24   b . The source electrode  15  is connected with the signal line  3 , which is laminated on the scanning line  2  and the common line  8  through the gate insulating film  9 . Furthermore, the driving electrode  5  and the opposite electrode  6  are formed through the passivation film  10 . The driving electrode  5  is connected with the drain electrode  16  through the contact hole  14 . The opposite electrode  6  is connected with the common line  8  through the through-hole  18 . The channel passivation film TFT can be used as the TFT  4 . 
   In the IPS liquid crystal displaying apparatus of Embodiment 2, as in Embodiment 1, the driving electrode  5  and the opposite electrode  6  are formed in a layer close to the liquid crystal different from the signal line  3 . As the liquid crystal can be driven more efficiently, the space between the driving electrode  5  and the opposite electrode  6  can be made wider to improve the aperture ratio. Since the common line  8  and the scanning line  2  are formed in the same layer, the common line  8  can be formed on the flat glass substrate  1  together with the scanning line  2 . Thus, a problem of disconnecting the common line  8  with a level difference portion is prevented from being caused, so as to improve traction defective. Therefore, the reliability of the product is improved. In Embodiment 1, the opposite electrode  6  cannot be made thinner in film due to resistivity of the common line  8 , but in Embodiment 2, the film of the opposite electrode  6  can be made thinner. The dispersion of the electrode space is made smaller due to the thinner film of the opposite electrode  6 , so as to realize a liquid crystal displaying apparatus which is less in uneven luminance across the whole picture face. 
   Embodiment 3 
     FIGS. 25   a  and  25   b  show the construction of one pixel of the liquid crystal displaying apparatus of the embodiment 2 of the present invention  FIG. 25   a  is its plain view.  FIG. 25   b  is a sectional view taken along a line of A-A of  FIG. 25   a .  FIGS. 26   a ,  26   b ,  27   a ,  27   b ,  28   a ,  28   b ,  29   a ,  29   b ,  30   a  and  30   b  are views showing the process flow of the array substrate. Referring to the drawing, reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a TFT, numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  12  denotes a BM, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of a transistor, and numeral  16  denotes a drain electrode. Numeral  20  denotes an array substrate comprising a glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  is an opposite substrate serving as a displaying picture face arranged opposite to the array substrate  20 . Numeral  40  denotes a slit which is a gap between the signal line  3  and the opposite electrode  6 . Numeral  50  denotes an opening of the pixel. 
   In forming the TFT array substrate  20 , the passivation film  10  is formed of a transparent insulation film such as silicon nitride, silicon oxide. The surface of the passivation film  10  is not flat and has a level difference. In Embodiment 3, the passivation film  10  is made flat by removing the level difference of the surface of the passivation film  10 , as shown in  FIG. 25   b  and  FIGS. 26   a ,  26   b ,  27   a ,  27   b ,  28   a ,  28   b ,  29   a ,  29   b ,  30   a  and  30   b , by forming with the use of a material such as acrylic melamine, acrylic epoxy or the like having a function of flattening the surface of the layer to be formed. 
   The IPS liquid crystal displaying apparatus of Embodiment 3 can equally constitute with precision the gap between the surface of the array substrate across the whole displaying picture face and the opposite substrate  30  by flattening the surface of the passivation film  10 . A liquid crystal displaying apparatus which is less in uneven brilliance across the whole picture face can be made. The fraction defective which is caused due to cracks or the like in the level difference portion of the passivation film  10  can be made smaller to improve the yield. A high quality liquid crystal displaying apparatus can be realized which is applied equally in rubbing treatment necessary to the orientation of the liquid crystal by the flattening operation and is less in orientation disturbing. 
   As in Embodiment 1, the driving electrode  5  and the opposite electrode  6  are provided closer to the liquid crystal than a formed layer of the signal line  3 , with an effect of improving the aperture ratio, because the liquid crystal can be driven efficiently, and the space between the driving electrode  5  and the opposite electrode  6  can be widened. 
   Embodiment 4 
     FIGS. 31   a  and  31   b  show the construction of one pixel electrode of the liquid crystal displaying apparatus of Embodiment 4 of the present invention  FIG. 31   a  is its plain view.  FIG. 31   b  is a sectional view taken along a line of A-A of  FIG. 31   a . Referring to the drawing, reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a TFT, numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of a TFT  4 , and numeral  16  denotes a drain electrode of the TFT. Numeral  20  denotes an array substrate composing a glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  denotes an opposite substrate serving as a displaying picture face arranged opposite to the array substrate  20 . Numeral  60  denotes a light shielding film provided on the glass substrate  1 . 
   Embodiment 4 is characterized by formation of a light shielding film  60  on a glass substrate  1 , which shields the leakage light from a slit  40  (see  FIG. 43   a ) between the signal line  3  and the opposite electrode  6  in the pixel structure of the liquid crystal displaying apparatus of Embodiment 1 through Embodiment 3. The structure of the liquid crystal displaying apparatus of Embodiment 4 will be described in accordance with  FIG. 31   a  and  FIG. 31   b.    
   A light shielding film  60  is formed on the glass substrate  1  in  FIG. 31   b . Although not shown in  FIG. 31   b , the scanning line  2  is also formed on the same layer as that of the light shielding film  60 . The scanning line  2  functions as a gate electrode of the TFT  4 . A gate insulating film  9  is laminated on the scanning line  2  and the light shielding film  60 . A signal line  3 , in a position superposed on the light shielding film  60 , on the gate insulating film  9 . The TFT  4  is also formed on the gate insulating film  9 . The TFT  4  can use either of the channel etch TFT and the channel passivation film TFT. The source electrode  15  of the TFT  4  and the drain electrode  16  are also formed in the same layer as that of the signal line  3 , so as to laminate the passivation film  10 . Continuously a contact hole  14  is formed in the passivation film  10 . The driving electrode  5  provided on the passivation film  10  and the drain electrode of the TFT  4  provided on the gate insulating film  9  are connected with each other through the contact hole  14 . 
   The opposite electrode  6  is formed on the passivation film  10  as in the driving electrode  5 . In a position where the opposite electrode  6  is superposed on the light shielding film  60 , it is superposed through the drain electrode  16  and the passivation film  10  to form the storage capacitance  7  for keeping the electric potential of the driving electrode  5 . The opposite electrode  6  is connected with the common line  8  provided on the same layer. Broken lines are shown on both the end portions of the pixel of  FIG. 31   a . The broken lines show a position in  FIG. 31   a  of the light shielding film  60  provided on the glass substrate  1  shown in  FIG. 31   b . As shown by the broken lines, it is found out that a slit  40  (see  FIG. 43   a ) is covered between the signal line  3  and the opposite electrode  6  by formation of the opposite electrodes  6  at both the ends to be superposed on the light shielding film  60 . 
   In Embodiment 4, the driving electrode  5  and the opposite electrode  6  are formed on the passivation film  10 . The driving electrode  5  and the signal line  3  are formed simultaneously on the gate insulating film  9  and the opposite electrode  6  can be formed after the passivation film has been formed by using silicon nitride or the like. In this case, the driving electrode  5  and the opposite electrode  6  are formed in a different layer. In Embodiment 4, the light leaking from the slit  40  (not shown) between the signal line  3  and the opposite electrode  6  is not caused by formation of the light shielding film  60  on the glass substrate  1 . Thus, the width of the BM  12  of the opposite substrate  30  can be made narrower and the light shielding in the direction of the signal line  3  do not have to be conducted by the BM  12 . Therefore, the BM  12  can be omitted so that the opening portion can be provided larger. 
   The liquid crystal displaying apparatus is manufactured by superposed combination between the TFT array substrate and the opposite substrate with a color filter attached to it, including the liquid crystal  11  into between these substrates, and connecting the driving circuit. Superposed errors are sometimes caused by a step of superposing the TFT array substrate and the opposed substrate. Thus, in the BM, the light shielding area has to be provided larger (see  FIG. 43   a ), considering the superposed errors, so as to positively shield the leakage light from the slit  40  of the TFT array substrate  20 . The transmission portion of the slit leakage light can be shielded in light positively by provision of the light shielding film  60  on the TFT array substrate  20 . The superposed error between the TFT array substrate and the opposite substrate is not necessary to be considered. Thus, the BM  12  can be provided into the size of a necessary minimum, and thereby the opening portion can be made larger. 
   In the IPS liquid crystal displaying apparatus of Embodiment 4, the driving electrode  5  and the opposite electrode  6  are provided in a layer close to the liquid crystal as in the IPS liquid crystal displaying apparatus of Embodiment 1. The liquid crystal can be driven effectively and the space between the electrodes can be widened, with an effect of improving the aperture ratio. 
   Embodiment 5 
   A construction of one pixel of the IPS liquid crystal displaying apparatus of Embodiment 5 is depicted in  FIGS. 32   a  and  32   b . The plain view thereof is depicted in  FIG. 32   a .  FIG. 32   b  is a sectional view taken along a line A-A of  FIG. 32   a . Referring to the drawing, reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  denotes a signal line, numeral  4  denotes a thin film transistor (TFT), numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  7  denotes an electrode for forming the storage capacitance, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  11  denotes a liquid crystal, numeral  12  denotes a BM, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of a transistor, and numeral  16  denotes a drain electrode of a transistor. Numeral  20  denotes an array substrate comprising glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . Numeral  30  denotes an opposite substrate serving as a displaying picture face arranged opposite to the array substrate  20 . 
   Embodiment 5 is characterized by formation of the driving electrode  5  and the opposite electrode  6 , as in Embodiment 1, in a layer upper than the signal line  3 , and furthermore, the formation of the opposite electrode  6  to cover the signal line  3 , so as to make it hard to receive the influences of the leakage electric field from the signal line  3  but further, not to cause the leakage light from the slit  40  (see  FIG. 43   a ) between the signal line  3  and the opposite electrode  6 .  FIG. 33  depicts the simulated results of changes in electric potential caused between the driving electrode  5  formed to cover the signal line  3  and the opposite electrode  6  formed in the same layer as that of the driving electrode  5 .  FIG. 33  is the calculated electric potential in the window upper portion or lower portion when a white window has been displayed on the half tone of 50% in relative transmission factor. 
   Between  FIG. 46  and  FIG. 33  there is shown the electric potential distribution in the TFT array substrate of the conventional IPS liquid crystal displaying apparatus having the driving electrode  5  and the opposite electrode  6  in the layer lower than the signal line  3 . In  FIG. 33 , the electric field to be caused by the electric potential difference between the signal line  3  and the opposite electrode  6  is shielded by the opposite electrode  6  arranged on the upper portion to cover the signal line  3 . Thus, the electric potential distribution is approximately symmetrical in the area close to the signal line  3  of the opening  50  and the area separated from the signal line  3 . 
   In this manner, the TFT array substrate  20  of the IPS liquid crystal displaying apparatus of Embodiment 5 can reduce remarkably the influences, of the electric field to be caused between the signal line  3  and the opposite electrode  6 , with respect to the electric field to be caused between the driving electrode  5  and the opposite electrode  6  by formation of the driving electrode  5  and the opposite electrode  6  in a layer upper than the signal line  3 , and formation of the opposite electrode  6  to cover the signal line  3 . The opposite electrode  6  of the end of the opening  50  can be made much closer to the signal line  3 , thus making it possible to widen the total area of the opening  50  wider. 
   As the opposite electrode  6  is formed to cover the signal line  3 , the leakage light can be shield, thus making it possible to remove the BM  12 . As the area of the opening portion  50  can be widened, a liquid crystal displaying apparatus higher in brilliance can be provided. As a step of providing the BM  12  can be reduced, the productivity can be improved, and a liquid crystal displaying apparatus can be produced with lower cost. As in Embodiment 1, the driving electrode  5  and the opposite electrode  6  can be formed in a layer close to the liquid crystal. The liquid crystal can be driven efficiently and the space between the electrodes can be widened, thus improving the aperture ratio. 
   Embodiment 6 
     FIGS. 34   a  and  34   b  show the construction of one pixel of the IPS liquid crystal displaying apparatus of Embodiment 6.  FIG. 34   a  is its plain view.  FIG. 34   b  is a sectional view taken along a line of A-A of  FIG. 34   a  The construction of the pixel of the IPS liquid crystal displaying apparatus of Embodiment 6 shown in  FIGS. 34   a  and  34   b  are fundamentally similar to that of the pixel of the IPS displaying apparatus of Embodiment 5 shown in  FIG. 12 , the description thereof is omitted. Although the opposite electrode  6  of the construction for completely covering the signal line  3  is provided in Embodiment 5, the opposite electrode  6  of the construction for covering one portion of the signal line  3  can be used as in the opposite electrode  6  of the pixel of the IPS liquid crystal displaying apparatus of Embodiment 6 shown in  FIGS. 34   a  and  34   b.    
   According to Embodiment 6, the opposite electrode  6  is adapted to form one portion of the signal line  3 . Thus, the electric field for generating the electric potential difference between the signal line  3  and the opposite electrode  6  can reduce the influences for influencing the electric field between the driving electrode  5  and the opposite electrode  6 , and the leakage light passing through the slit  40  between the signal line  3  and the opposite electrode  6  can be shielded. It is possible to make the width of the BM  12  narrower or remove the BM  12 . A liquid crystal displaying apparatus which is wider in an opening and higher in luminance can be realized. Also, a process of providing the BM  12  can be reduced by removing the BM  12 , so as to improve the productivity. As a superposed area of the signal line  3  and the opposite electrode  6  becomes smaller, the short circuit defect between the signal line  3  and the opposite electrode  6  can be reduced. As the superposed area of the signal line  3  and the opposite electrode  6  becomes smaller, the capacitance between the signal line  3  and the opposite electrode  6  can be made smaller, so that the load of the wiring can be reduced, making it easier to do a driving operation. 
   Embodiment 7 
     FIGS. 35   a  and  35   b  show the construction of one pixel of the IPS liquid crystal displaying apparatus of Embodiment 7.  FIG. 35   a  is its plain view.  FIG. 35   b  is a sectional view taken along a line of A-A of  FIG. 35   a . As the construction of the pixel of the IPS liquid crystal displaying apparatus of Embodiment 7 shown in  FIGS. 35   a  and  35   b  are fundamentally similar to that of the pixel of the IPS type displaying apparatus of the embodiment 5 shown in  FIGS. 34   a  and  34   b , the description thereof is omitted. Embodiment 7 is characterized by enlarging the opposite electrode  6  up to above the scanning line  2 , and connecting the opposite electrode  6  of the other pixel adjacent to the pixel by using the opposite electrode  6 , in the pixel construction of the liquid crystal displaying apparatus in, for example, Embodiment 6 as shown in  FIGS. 34   a  and  34   b.    
   By using such a construction, the width of the opposite electrode  6  becomes thicker so that the resistivity of the opposite electrode  6  is lowered and the load is reduced, making it easier to conduct a driving operation. As the electric potential is supplied from the opposite electrode  6  on the scanning line  2  even when the common line  8  is disconnected, it does not become defective on display. The reliability of the product is improved. The construction of the opposite electrode  6  in Embodiment 7 can be adapted to not only to Embodiment 7, but also the other embodiments. 
   Embodiment 8 
     FIG. 36  shows the sectional construction of the storage capacitance portion of one pixel of the liquid crystal displaying apparatus of Embodiment 8 of the present invention. Referring to the drawing, reference numeral  17  denotes an electrode for increasing the storage capacitance formed on the glass substrate  1 . Numeral  16  denotes a drain electrode of the TFT. The storage capacitance portion of the liquid crystal liquid displaying apparatus of Embodiment 8 as shown in the drawing is superposed and laminated on a layer (for example, the layer of the scanning line  2 ) separate from the drain electrode  16  of the TFT through the gate insulating film  9 . It can make the area of the electrode for forming the storage capacitance smaller by the laminating construction of the electrode of the storage capacitance portion. As a result, the opening  50  (not shown) of the pixel can be made wider. 
   Embodiment  9   
     FIGS. 37   a ,  37   b ,  38   a ,  38   b ,  39   a ,  39   b ,  40   a ,  40   b ,  41   a ,  41   b ,  42   a  and  42   b  are views showing the process flow of the TFT array substrate of the Embodiment 9. Referring to  FIGS. 37   a ,  37   b ,  38   a ,  38   b ,  39   a ,  39   b ,  40   a ,  40   b ,  41   a ,  41   b ,  42   a  and  42   b , reference numeral  1  denotes a glass substrate, numeral  2  denotes a scanning line, numeral  3  is a signal line, numeral  4  denotes a TFT, numeral  5  denotes a driving electrode, numeral  6  denotes an opposite electrode, numeral  8  denotes common line, numeral  9  denotes a gate insulating film, numeral  10  denotes a passivation film, numeral  14  denotes a contact hole, numeral  15  denotes a source electrode of a transistor, and numeral  16  denotes a drain electrode of a transistor. Numeral  19  denotes a second passivation film. Numeral  20  denotes an array substrate comprising a glass substrate  1 , a signal line  3 , a driving electrode  5 , an opposite electrode  6 . 
   In Embodiment 9, a second passivation film  19  is formed on the TFT array substrate shown in  FIGS. 4   a  through  18   a  and  FIGS. 4   b  through  18   b . The construction of one pixel of the liquid crystal displaying apparatus of Embodiment 9 is similar to Embodiment 1. A method of manufacturing the liquid crystal displaying apparatus of the embodiment will be described hereinafter. The process flow of the TFT array substrate in Embodiment 9 is similar to Embodiment 1 up to a step for forming the opposite electrode  6 . In Embodiment 9, a second passivation film  19  is formed on the top layer of the opposite electrode  6 . 
   By forming the second passivation film  19  between the driving electrode  5  and the opposite electrode  6 , the short circuit, between the driving electrode  5  and the opposite electrode  6 , due to foreign materials can be prevented to improve the yield. As the level difference between the driving electrode  5  and the opposite electrode  6  can be made flat, a high quality of liquid crystal displaying apparatus can be realized where the rubbing treatment necessary for the liquid crystal orientation is equally applied and is less in orientation disturbing. 
   According to the IPS liquid crystal displaying apparatus of the present invention, the driving electrode and the opposite electrode are formed in a layer close to the liquid crystal different to the signal line. The driving electrode and the opposite electrode are formed in a layer close to the liquid crystal so that the liquid crystal can be driven more efficiently. Thus, the space between the driving electrode and the opposite electrode can be widened, so as to improve the aperture ratio. 
   According to the IPS liquid crystal displaying apparatus of the present invention, at least the opposite electrode of the driving electrode and the opposite electrode is formed in a layer close to the liquid crystal different from a layer where the signal line is formed, so that influences given by the electric field to be caused by the electric potential difference between the signal line and the opposite electrode. 
   According to the IPS liquid crystal displaying apparatus of the present invention, the opposite electrode is formed to cover one portion or all the portion of the signal line. The electric field to be caused by the electric potential difference between the signal line and the opposite electrode influences the electric field to be caused between the driving electrode of the opening and the opposite electrode, thereby restraining a problem of deteriorating the picture quality on the displaying from being caused. Thus, the liquid crystal display of high picture quality can be made and the leakage light from between the signal line for making the black light a light source, and the opposite electrode can be shielded accurately. The BM can be removed, so as to improve the aperture ratio. 
   According to the IPS liquid crystal displaying apparatus of the present invention, at least the opposite electrode is provided in a layer different from the scanning line so as to cover one portion or all the portion of the scanning line. The opposite electrode of the other pixel can be connected by the opposite electrode, so that the width of the opposite electrode can be made thicker without reduction in the area of the opening. Accordingly, the resistivity of the opposite electrode can be lowered to reduce the load of the wiring. As the electric potential can be fed from the opposite electrode on the scanning line when the common line is disconnected, the reliability can be increased by restraining the defects on the displaying from being caused. 
   According to the IPS liquid crystal displaying apparatus of the present invention, the common line and the scanning line are provided on the same layer and the single line is provided on a layer closer to the opposite substrate than to the common line and the scanning line. The defect to be caused in the stage difference portion can be restrained. 
   According to the IPS liquid crystal apparatus of the present invention, a passivation film which formed approximately flat in surface where the TFT array substrate comes into contact with the liquid crystal. Thus, the gap between the array substrate surface and the opposite substrate across all the display picture surface is equally constructed with precision. The rubbing treatment necessary for the liquid crystal orientation is equally applied and the orientation disturbing can be reduced. The liquid crystal displaying apparatus which is less in uneven luminance across the whole picture face can be realized. The fraction defective which is caused by cracks in the stage difference portion of the passivation film becomes smaller, so as to improve the yield. 
   In the IPS liquid crystal displaying apparatus of the present invention, a TFT array substrate is provided having a light shielding means formed to have the signal line and the opposite electrode superposed. The leakage light for transmitting through the slit can be shielded, and thus the BM provided on the opposite substrate becomes unnecessary. The superposed errors are not necessary to be considered in the superposition between the TFT array substrate and the opposite substrate in determining the size of the light shielding means. Thus, the size of the light shielding means can be made that of a necessary minimum, so as to improve the aperture ratio. 
   According to the in plain switching type liquid crystal displaying apparatus of the present invention, a TFT array substrate formed to be superposed with a TFT, a driving electrode, and a storage capacitance increasing electrode being different in layer. The area of the electrode for forming the storage capacitance can be made smaller and the opening portion of the pixel can be made wider correspondingly, and the liquid crystal displaying apparatus higher in luminance can be realized. 
   Though several embodiments of the present invention are described above, it is to be understood that the present invention is not limited only to the above-mentioned, various changes and modifications may be made in the invention without departing from the spirit and scope thereof.