Patent Abstract:
An electronic device having an active matrix liquid crystal device comprising a sealing layer with a region overlapping an insulating film formed over another insulating film, which extends beyond said insulating film and forms on a peripheral switching device, a region in contact with said another insulating film, and a region where said second insulating film is not formed over said another insulating film.

Full Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   This application is a continuation application of and claims priority to U.S. application Ser. No. 10/143,331, filed May 9, 2002, now U.S. Pat. No. 6,577,372, which is a continuation of U.S. application Ser. No. 09/912,092, filed Jul. 23, 2001, now U.S. Pat. No. 6,404,479, which is a continuation of U.S. application Ser. No. 08/879,583, filed June 20, 1997, now U.S. Pat. No. 6,288,764. 

   BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a configuration of an active matrix type liquid crystal display integrated with a peripheral driving circuit. 
   2. Description of Related Art 
   Active matrix type liquid crystal displays have been known. 
   They have a configuration in which an active matrix circuit and a peripheral driving circuit for driving the same circuit are integrated on a glass substrate or quartz substrate. 
   In such a liquid crystal panel integrated with a peripheral driving circuit, a thin film semiconductor that forms thin film transistors provided in the peripheral driving circuit must be a crystalline silicon thin film. The reason for this is that the peripheral driving circuit must operate at a high speed. 
   Reliability is an important consideration for a liquid crystal panel integrated with a peripheral driving circuit as described above. Specifically, what is important for such a device is the stability of image display in relation to the environment where it is used. 
   Especially, a crystalline silicon film has a problem in that it is significantly susceptible to the variation of characteristics with time and the influence of the environment where it is used because of the high level of characteristics of itself. 
   Specifically, a problem arises in that it is affected by stresses exerted thereon during the fabrication and handling of a liquid crystal panel and by moisture that permeates into the liquid crystal panel. 
   Further, a liquid crystal panel integrated with a peripheral driving circuit is designed in an intention to minimize the surface area of regions unnecessary for screen display. For example, efforts are put in minimizing the surface area occupied by the peripheral driving circuit. 
   Meanwhile, in a liquid crystal display, an encapsulating material for enclosing liquid crystal, referred to as “sealing material” is provided at a peripheral portion to hold liquid crystal between a pair of substrates. 
   As an effort to minimize the surface area of regions unnecessary for screen display as described above, the surface area occupied by the sealing material must be also reduced. A configuration for this purpose is known in which a sealing material is provided on a peripheral driving circuit to minimize the surface area excluding pixels (referred to as “frame”). 
   In the case of an active matrix type liquid crystal display integrated with a peripheral driving circuit, faults that occur in the peripheral driving circuit can be a problem. 
   Especially, the configuration in which a sealing material is provided on a peripheral driving circuit to minimize the surface area excluding pixels (referred to as “frame”) is subjected to more faults at the peripheral driving circuit. 
   This problem occurs due to the following reasons. A sealing material includes a kind of spacer referred to as “filler” for maintaining a gap between substrates. 
   In general, a peripheral driving circuit is at a high level of integration. As a result, thin film transistors and wiring lines located directly under such fillers are subjected to a pressure from the fillers (it is assumed that this pressure can be locally quite high) and are hence vulnerable to line breakage and poor contact. 
   Meanwhile, a spherical substrate gap maintaining means referred to as “spacer” is used also in an active matrix region. However, since an active matrix region is at a lower level of integration, faults attributable to the presence of a spacer are not as problematic as in a peripheral driving circuit. 
   It is an object of the invention disclosed in this specification to provide a configuration for an active matrix type liquid crystal display incorporating a peripheral driving circuit, in which the surface area excluding the region of a pixel matrix circuit is minimized. 
   On the basis of the above-described configuration, it is another object of the invention to provide a configuration that prevents breakage of thin film transistors provided on a peripheral driving circuit due to a pressure exerted by a sealing material. 
   It is still another object of the invention to provide a configuration for an active matrix type liquid crystal display incorporating a peripheral driving circuit, which prevents thin film transistors from being adversely affected by a stress exerted thereon during the fabrication and handling of the liquid crystal panel and which prevents moisture from permeating into the liquid crystal panel. 
   SUMMARY OF THE INVENTION 
   In order to solve the above-described problems, as a mode of carrying out the invention disclosed in this specification, there is provided an active matrix type liquid crystal display integrated with a peripheral driving circuit as shown in  FIG. 1  having a configuration in which: 
   a sealing material  104  is provided on the peripheral driving circuit; and 
   resin layers  237  and  240  are provided between the peripheral driving circuit and the sealing material. 
   The above-described configuration makes it possible to prevent a high pressure from being locally applied to the peripheral driving circuit by a filler  103  included in the sealing material  104 , thereby preventing the breakage of the peripheral driving circuit. 
   Further, by providing the sealing material on the peripheral driving circuit, a configuration can be obtained in which the surface area excluding the pixel region is minimized. 
   In the above-described configuration, each of the resin layers are preferably formed as multilayered form. This is effective in moderating the pressure exerted thereon by the filler in the sealing material. 
   Further, it is advantageous to form an auxiliary capacitor in the active matrix region using the resin layers. This makes it possible to provide a capacitor having a required value in a pixel. 
   The thickness of the resin layers is preferably equal to greater than one-half of the diameter of a filler in the sealing material. This is a condition advantageous in preventing the pressure of a filler in the sealing material from being exerted on the peripheral driving circuit even if the filler sinks into the resin layers. Further, in order to moderate a pressure exerted on the peripheral driving circuit, a highly elastic material such as polyimide may be chosen for the resin layers. When the resin layers are formed as a multilayered form, it will be sufficient if the collective thickness is equal to or greater than one-half of the diameter of a filler in the sealing material. 
   In order to solve the above-described problems, as specifically illustrated in  FIG. 6 , there is provided a configuration in which a liquid crystal material  314  is sandwiched and held between a pair of glass substrates  301  and  318 , characterized in that: 
   an active matrix circuit (constituted by a thin film transistor indicated by  302 ) and a peripheral driving circuit (constituted by a thin film transistor indicated by  303 ) are provided on the surface of one of the substrates  301 ; 
   a resin material is provided on the peripheral driving circuit as interlayer insulating films  306 ,  309 , and  311 ; 
   the liquid crystal material  314  is sealed with a sealing material  315 ; 
   the resin material and the sealing material partially overlap with each other; and 
   the resin material is blocked from the outside by the sealing material. 
   In the context of the present invention, the term “a surface of a substrate” means a surface of a glass or quartz substrate and further a surface of a glass or quartz substrate having a silicon oxide film or a silicon nitride film (so-called inorganic film) formed thereon. 
   The use of the above-described configuration makes it possible to moderate a stress exerted on the peripheral driving circuit and to enhance sealing capability in the region indicated by  300  in  FIG. 6 . 
   Especially, a high degree of adhesion can be achieved in the region indicated by  350  in  FIG. 7  where the sealing material  315  is in contact with a silicon nitride film  305  which is an inorganic substance (inorganic film) except the region of wiring line  308 . This makes it possible to achieve a high degree of adhesion in this region, thereby preventing external moisture from permeating. 
   In order to moderate a stress, the interlayer insulating films are preferably formed from polyimide resin. The sealing material is preferably formed from epoxy resin to enhance the sealing action further. 
   The interlayer insulating films can be formed without using polyimide resin. 
   For example, acrylic resin is also used to form the interlayer insulating film. 
   The active matrix type liquid crystal displays integrated with a peripheral circuit shown in  FIGS. 1 and 6  are used for display devices of photographic apparatuses such as portable video movie apparatuses, portable personal computers, and various information terminals. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a partial sectional view of an active matrix type liquid crystal display which utilizes the present invention. 
       FIGS. 2A through 2E  illustrate fabrication steps to provide the configuration shown in  FIG. 1 . 
       FIGS. 3A through 3D  illustrate fabrication steps to provide the configuration shown in  FIG. 1 . 
       FIG. 4  illustrates a fabrication step to provide the configuration shown in  FIG. 1 . 
       FIG. 5  is a partial sectional view of another active matrix type liquid crystal display which utilizes the present invention. 
       FIG. 6  is a partial sectional view of a liquid crystal panel which utilizes the present invention. 
       FIG. 7  is a partial sectional view of a liquid crystal panel which utilizes the present invention. 
       FIG. 8  is a partial sectional view of a liquid crystal panel which utilizes the present invention. 
       FIG. 9  is a partial sectional view of a liquid crystal panel which utilizes the present invention. 
       FIG. 10  is a partial sectional view of a liquid crystal panel which utilizes the present invention. 
       FIGS. 11A through 11F  are views schematically showing apparatuses which utilize the present invention. 
   

   DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
   A first embodiment of the present invention will now be described. 
   The present embodiment employs a configuration in which a sealing material is provided on a region where a peripheral driving circuit is located. Further, in order to prevent damage to the peripheral driving circuit caused by a stress exerted by a filler included in the sealing material, a configuration is employed in which a buffer layer made of polyimide is provided on the peripheral driving circuit. 
     FIG. 1  is a partial sectional view of an active matrix type liquid crystal display according to the present embodiment.  FIG. 1  shows a configuration referred to as “peripheral driving circuit integrated type” having a structure in which a peripheral driving circuit  100  and an active matrix circuit  200  are integrated on the same substrate. 
   In the configuration shown in  FIG. 1 , a sealing portion indicated by  104  is provided over the peripheral driving circuit  100  and bounded by spacer  103 . This sealing portion has a sealing function to prevent liquid crystal filled in a space  105  (a gap between the substrates) from leaking out. 
   The sealing portion  104  is formed from a resin material. The sealing portion  104  is formed by applying the resin material with a spinner, patterning it, and further baking it. Alternatively, it is formed using a printing process. 
     103  designates a filler which is required for maintaining an interval between the substrates. This filler is made of a resin material and has a cylindrical configuration. In the present embodiment, the resin material used for forming the sealing material  104  includes the filler  103  which is mixed therein in advance. 
   Resin layers  237  and  240  are provided under the sealing material  104 . The resin layers are used as interlayer insulating films and dielectrics for an auxiliary capacitor. The resin layers have a function of moderating a pressure exerted on the peripheral driving circuit  100  by the filler in the sealing material in the region of the peripheral driving circuit  100 . 
     FIGS. 2A through 2E ,  FIGS. 3A through 3D , and  FIG. 4  illustrate fabrication steps to provide the configuration shown in  FIG. 1 . The fabrication steps described below relate to a configuration in which an n-channel type thin film transistor and a p-channel type thin film transistor are provided in a peripheral driving circuit and in which a p-channel type thin film transistor is provided in an active matrix circuit. 
   More particularly, in this configuration, a low concentration impurity region is provided in the n-channel type thin film transistor, and a high concentration impurity region is provided between a source/drain region and a channel formation region of the p-channel type thin film transistor. 
   Such a configuration makes it possible to suppress deterioration of the characteristics of the n-channel type thin film transistor of the peripheral driving circuit. Further, the active matrix circuit can be configured to achieve a low OFF current value and less variation of an ON current value. 
     FIGS. 2A through 2E ,  FIGS. 3A through 3D , and  FIG. 4  illustrate fabrication steps.  FIGS. 2A through 2E  illustrate steps for fabricating the n-channel type thin film transistor (and the region around the same) provided in the peripheral driving circuit on the left side thereof. They illustrate steps for fabricating the thin film transistor (and the region around the same) provided in the active matrix region on the right side thereof. 
   First, as shown in  FIG. 2A , a backing film (not shown) is formed on a glass substrate  201 . A silicon oxide film is used as the backing film. This backing film has a function of preventing diffusion of impurities from the glass substrate  201  and moderating a stress to the glass substrate. 
   Next, an amorphous silicon film (not shown) is formed on the backing film to a thickness of 500 Å using a plasma CVD process. Further, the amorphous silicon film is irradiated with laser beams to be crystallized into a crystalline silicon film. The crystalline silicon film may be obtained using a heating process or irradiation with intense beams. 
   This crystalline silicon film is patterned to form active layers indicated by  202  and  203  of thin film transistors.  202  designates an active layer of the n-channel type thin film transistor provided in the peripheral driving circuit  100 .  203  designates an active layer of the p-channel type thin film transistor provided in the active matrix circuit  200 . 
   Although only two thin film transistors are shown in the figures, tens of thousands to hundreds of thousands (or more) of thin film transistors are integrated in an actual configuration. 
   After forming the active layers, a plasma CVD process is performed to form a silicon oxide film having a thickness of 1000 Å as a gate insulating film  204 . Thus, the state shown in  FIG. 2A  is achieved. 
   In the state shown in  FIG. 2A , an aluminum film (not shown) is formed by a sputtering process to a thickness of 4000 Å in order to configure gate electrodes (and gate lines). This aluminum film includes 0.1% by weight of scandium. 
   Next, an anodic oxidation film (not shown) having dense film quality is formed to a thickness of 100 Å. This anodic oxidation is carried out using an ethylene glycol solution including 3% of tartaric acid as the electrolyte. This solution is used after being neutralized with aqueous ammonia. 
   The anodic oxidation film has a function of enhancing the adhesion of resist masks to be provided later. A silicon nitride film or a metal film may be used instead of the anodic oxidation film. Alternatively, an aluminum oxide film may be formed by means of plasma oxidization in an oxidizing atmosphere. 
   Next, the aluminum film is patterned using resist masks  205  and  206 . This step forms aluminum patterns indicated by  207  and  208  which serve as bases for the gate electrodes. Thus, the state shown in  FIG. 2B  is achieved. 
   In the state shown in  FIG. 2B , anodic oxidation is performed using the aluminum patterns  207  and  208  as anodes. This step forms porous anodic oxides (it is not appropriate to express them as “films”) indicated by  211  and  212 . The anodic oxides are grown a distance of 5000 Å. 
   This anodic oxidation is carried out using an aqueous solution including 3% of oxalic acid as the electrolyte. 
   At this step, the presence of the resist masks  205  and  206  causes the anodic oxidation to selectively proceed on side surfaces of the aluminum patterns  207  and  208 . The reason is that the presence of the resist masks  205  and  206  prevents the electrolyte from contacting the upper surfaces of the aluminum patterns  207  and  208 . The patterns indicated by  209  and  210  here will become gate electrodes later. Thus, the state shown in  FIG. 2C  is achieved. 
   Next, the resist masks  205  and  206  are removed. Then, anodic oxidation films having dense film quality are formed. This anodic oxidation is performed using an ethylene glycol solution including 3% of tartaric acid and neutralized with aqueous ammonia as the electrolyte. 
   At this step, the electrolyte penetrates the porous anodic oxide films  211  and  212 . Therefore, dense anodic oxidation films indicated by  213  and  214  are formed. 
   This step defines gate electrodes  209  and  210 . The surfaces of these electrodes are covered by the dense anodic oxidation films  213  and  214 . These electrodes and wiring lines extending therefrom serve as wiring lines for a first layer. Thus, the state shown in  FIG. 2D  is achieved. 
   Next, the implantation of P (phosphorus) ions is carried out on the entire surface. At this step, P ions are implanted at a relatively high concentration in order to form source and drain regions ( FIG. 2E ). 
   At this step, P ions are implanted in regions  215 ,  217 ,  218 , and  220 . P ions are not implanted in regions  216  and  219 . 
   Then, the porous anodic oxide films  211  and  212  are removed. Thus, the state shown in  FIG. 3A  is achieved. In this state, P ions are implanted again. At this step, P ions are implanted in a dose less than that in the doping condition shown in  FIG. 2E . 
   Thus, the regions indicated by  221 ,  222 ,  223 , and  224  are formed as low concentration impurity regions, and a channel formation region  225  of the n-channel type transistor is defined ( FIG. 3A ). 
   Next, the region where the n-channel type thin film transistor is to be formed is covered with a resist mask  226 , and B ions are implanted in such a state. This step is performed on a condition that the regions indicated by  227  and  228  become the source and drain regions of the p-channel type thin film transistor. 
   At this step, the regions indicated by  227  and  228  become the source and drain regions. Further, the regions indicated by  229  and  230  are formed as regions which exhibit stronger p-type properties than those in the regions indicated by  227  and  228 . 
   This is because the concentration of P elements included in the regions  229  and  230  is lower than that in the regions  227  and  228 . 
   Specifically, more B elements are required in the regions  227  and  228  to neutralize P elements and, as a result, the regions  229  and  230  exhibit stronger p-type properties. Further, the region indicated by  231  is defined as the channel formation region of the p-channel type thin film transistor. 
   When the implantation of impurity ions is complete, the resist mask  226  is removed. Then, laser irradiation is performed to activate the implanted impurities and to anneal damage on the semiconductor films caused by the impact of the ions. 
   Next, a first interlayer insulating film  232  is formed. A silicon nitride film having a thickness of 4000 Å is formed here as the interlayer insulating film  232  using a plasma CVD process. 
   Then, contact holes are formed to form wiring lines (electrodes)  233  through  236  in a second layer. Thus, the state shown in  FIG. 3C  is achieved. 
   Next, a second interlayer insulating film  237  is formed. A resin film having a thickness of 15000 Å is formed here as the interlayer insulating film  237 . It is formed using a spin coating process. 
   Next, a contact hole is formed to form a wiring line (electrode)  238  in a third layer. At the same time, a light shield film  239  for shading the thin film transistor provided in the active matrix circuit  200  is formed. This light shield film  239  forms an auxiliary capacitor in cooperation with a pixel electrode which is opposite thereto across a interlayer insulating film (resin film) to be formed later. Thus, the state shown in  FIG. 3D  is achieved. 
   Next, a third interlayer insulating film  240  is formed as shown in  FIG. 4 . A resin layer having a thickness of 5000 Å is formed here as the third interlayer insulating film  240  using a spin coating process. Then, a contact hole is formed to form a pixel electrode  241  using ITO. 
   In the present embodiment, an auxiliary capacitor is formed by the light shield film  239  and the pixel electrode which are provided so as to sandwich the third interlayer insulating film (resin film)  240 . 
   Further, a rubbing film  242  is formed. The rubbing film  242  is made of resin and is formed using a printing process. In the present embodiment, the rubbing film is formed only in the region of the active matrix circuit. A rubbing process is carried out after the rubbing film  242  is formed. 
   Then, an opposite substrate  108  is provided as shown in  FIG. 1 . An opposite electrode  107  and a rubbing film  106  are formed on the opposite substrate  108 . The opposite substrate  108  and the substrate shown in  FIG. 4  is put together to complete the configuration shown in  FIG. 1 . 
   A second embodiment of the present invention will now be described. 
   The present embodiment is an example in which bottom-gate type thin film transistors are used in a liquid crystal display integrated with a peripheral driving circuit. 
     FIG. 5  is a sectional view corresponding to  FIG. 1 . The present embodiment is different from the configuration shown in  FIG. 1  in the structure of the thin film transistors. The configuration is otherwise similar to that shown in  FIG. 1 . 
   A third embodiment of the present invention will now be described. 
     FIG. 6  schematically shows the configuration of the present embodiment.  FIG. 6  is a schematic sectional view of an active matrix type liquid crystal display integrated with a peripheral driving circuit. 
   In  FIG. 6 ,  301  and  318  designate a pair of glass substrates that constitute a liquid crystal panel. A liquid crystal material, an active matrix circuit, and a peripheral driving circuit for driving the active matrix circuit are provided in a gap between the pair of glass substrates. 
     302  designates a thin film transistor provided in the active matrix circuit portion. Although only one thin film transistor is provided in  FIG. 6 , in practice, thin film transistors are provided in a quantity at least equal to the number of pixels. 
     303  designates a thin film transistor provided in the peripheral driving circuit. Although only one thin film transistor  303  is provided in  FIG. 6 , in practice, a combination of p-channel type and n-channel type thin film transistors is provided in quantities required for forming a shift register circuit and a buffer circuit. 
     304  designates a interlayer insulating film. The gate insulating film  304  is constituted by a silicon oxide film.  305  designates a silicon nitride film that constitutes a first interlayer insulating film. 
     306  designates a resin interlayer film made of polyimide that constitutes the first interlayer insulating film in combination with the silicon nitride film  305 . The resin interlayer film  306  made of polyimide is characterized in that its surface can be flattened. 
     307  designates a line which extends from the drain of the thin-film transistor  303  provided in the peripheral driving circuit and which is connected to the source of the thin film transistor  302  provided in the pixel matrix circuit. 
     308  designates a line connected to the source of the thin film transistor  303  provided in the peripheral driving circuit. This line  308  constitutes an external terminal of the liquid crystal panel. 
     309  designates a resin interlayer film made of polyimide that constitutes a second interlayer insulating film.  310  designates a light shield film made of titanium formed on the resin interlayer film  309  that constitutes the second interlayer insulating film. This light shield film  310  is provided to prevent the thin film transistor  302  from being irradiated with light. 
     311  designates a resin interlayer film made of polyimide that constitutes a third interlayer insulating film.  312  designates an ITO film that constitutes a pixel electrode. The ITO film  312  and the light shield film  310  form an auxiliary capacitor through the resin interlayer film  311 . Such a configuration makes it possible to obtain a required auxiliary capacitor without reducing the aperture ratio. 
   The resin interlayer films  306 ,  309  and  311  can be formed without using polyimide resin. For example, acrylic resin is also used to form the interlayer insulating film. 
     313  designates an orientation film made of polyimide. This orientation film  313  exerts an orientation regulating force on liquid crystal  314  which is in contact therewith. 
     315  designates epoxy resin for sealing the liquid crystal material. The liquid crystal material  314  is held between the pair of glass substrates  318  and  301  by the epoxy resin  315 . 
   The epoxy resin  315  includes glass fibers referred to as “filler” for maintaining the gap for the liquid crystal layer. 
     316  designates an orientation film made of polyimide provided on the opposite substrate (the substrate  318  is referred to as “opposite substrate”).  317  designates an opposite electrode. 
   The present embodiment is characterized in that the resin films  311 ,  309 , and  306  that constitute interlayer films overlap the epoxy resin  315  that constitutes a sealing material in regions except a part of the epoxy resin  315 . 
   This makes it possible to moderate a stress using the resin interlayer films made of polyimide and to prevent moisture from permeating from the outside of the panel using the epoxy resin that constitutes a sealing material. 
   The resin films indicated by  311 ,  309 , and  306  are elastic and have a function of moderating a stress exerted externally. 
   However, they substantially have no function as a barrier to prevent the penetration of moisture because they absorb moisture. 
   On the other hand, the epoxy resin  315  that constitutes a sealing material is rigid and substantially has no function of moderating a stress, but it has a sufficient function of blocking moisture. 
   The use of the configuration disclosed in the present embodiment allows the effects of both of those components to be demonstrated. 
   Especially, the degree of sealing can be improved where the epoxy resin film and the polyimide resin film do not overlap each other at the part. Specifically, since epoxy resin and polyimide exhibit poor adhesion to each other, the arrangement to prevent them from overlapping each other at the part indicated by  300  makes it possible to enhance a sealing effect provided by epoxy resin in such a part. 
   It is thus possible to provide a function of sealing liquid crystal in the cell at the part indicated by  300  and to obtain a configuration that prevents impurities and dusts from entering the liquid crystal layer from the outside. 
     FIG. 7  is a sectional view of a region where the wiring line  308  is not present. As apparent from  FIG. 7 , in the region indicated by  350 , a high degree of adhesion can be achieved between the sealing material  315  and the silicon nitride film  305  because they are in direct contact with each other. 
   The inventors understand that a quite high degree of adhesion can be achieved between epoxy resin and an inorganic material. It is therefore quite advantageous to enhance the sealing of the liquid crystal cell at the region indicated by  350  in  FIG. 7 . 
   Further, the structure of the thin film transistor is not limited to the top-gate type as in the present embodiment but may be a inverted staggered type as in the second embodiment. 
   A fourth embodiment of the present invention will now be described. 
   The present embodiment relates to an improvement on the configuration according to the third embodiment. Sealing may not be maintained in the region indicated by  300  in  FIG. 6  because of a step which is a result of the presence of the wiring line  308 . 
   The present embodiment is a device for solving this problem.  FIG. 8  shows a section of the region  308  in  FIG. 8  as viewed from the righthand side of  FIG. 6 . The reference numbers in  FIG. 8  which are the same as those in  FIGS. 6 and 7  designate the same locations. 
   In the present embodiment, a silicon oxide film  400  is formed by applying a solution after forming the wiring line  308 . Such a silicon oxide film has already been put in actual use as a final passivation film or flat film of an integrated circuit. 
     FIG. 9  shows a section as viewed from the right-hand side of  FIG. 8 . Since a silicon oxide film  400  is formed by applying a solution, a step as indicated by  401  can be filled. This makes it possible to improve the adhesion of the sealing material formed thereon to achieve a preferable sealing function. 
   As apparent from  FIG. 9 , it is necessary to remove the silicon oxide film  400  above the end of the line  308  to maintain contact with the outside.  FIG. 9  may be regarded as corresponding to  FIG. 6 . 
   A fifth embodiment of the present invention will now be described. 
   The present embodiment relates to a configuration for preventing the breakage and poor conductivity at the line  308  as a result of the application of a stress from the sealing material  315  at the end of the sealing material indicated by  300  in  FIG. 6 . 
   The wiring line  308  may be subjected to a stress from the sealing material  315  depending on the type of the epoxy resin that forms the sealing material  315  and hardening conditions for the same, and defects may occasionally occur in the wiring line  308 . 
   Under such circumstances, according to the present embodiment, the wiring line  308  is patterned as shown in  FIG. 10  under the sealing material  315 . 
   This makes it possible to prevent the occurrence of defects at the wiring pattern  308  as a result of the application of a stress from the sealing material  315 . 
   In addition, it is possible to suppress the reduction of sealing properties at side surfaces of the pattern of the wiring line  308  as shown in the fourth embodiment. 
   A sixth embodiment of the present invention will now be described. 
   The present embodiment shows examples of apparatuses having liquid crystal panels as described in the first through fifth embodiments. Configurations as shown in  FIGS. 11A through 11F  can be used on liquid crystal panels included in such apparatuses.  FIG. 11A  shows a portable information processing terminal. This apparatus includes a main body  2001  having a display device  2003  utilizing a liquid crystal panel, operation buttons  2004 , and a CCD camera  2002 . This apparatus has a configuration which allows information to be obtained and transmitted over a telephone network. 
   As the liquid crystal panel used for the display device, a transmission type or reflection type panel may be used. A reflection type panel is advantageous if power consumption is to be reduced. 
     FIG. 11B  shows an apparatus referred to as “head mount display” which is put on the head of a user and displays images just in front of the eyes, thereby performing a function of displaying images as if they were real scenes in front of the user. This apparatus includes a liquid crystal display  2102  at a display device portion and has a structure such that a main body  2101  is secured to the head of the user with a band  2103 . 
   As the liquid crystal panel, a transmission type or reflection type panel may be used. 
     FIG. 11C  shows a so-called car navigation system having a main body  2201  on which a display device  2202  utilizing a liquid crystal panel and operation buttons  2203  are provided and has a function of receiving waves from broadcast satellites by an antenna  2204 . 
   As the liquid crystal panel, a transmission type or reflection type panel may be used. 
     FIG. 11D  shows a portable telephone having a main body  2301  on which a display device  2304  utilizing a liquid crystal display, an audio input portion  2303 , an audio output portion  2302 , operation buttons  2305 , and an antenna  2306  are provided. 
     FIG. 11E  shows a video camera having a main body  2401  on which operation buttons  2404 , a display device  2402  constituted by a liquid crystal display, an eyepiece  2403  for viewing images displayed on the display device  2402 , and a tape holder  2405  for containing a magnetic tape for storing photographed images are provided. 
   As the liquid crystal panel forming the display device  2402 , a transmission type panel is normally used which forms images by modulating light from a back-light device. 
     FIG. 11F  shows a projection type projector in which a display device  2503  for optically modulating light from a light source is provided at a main body  2501  thereof. The display device  2503  shown in  FIG. 11F  is a device constituted by a reflection type liquid crystal panel. 
   An image which has been optically modulated by the display device is magnified by an optical system  2504  and is projected on a screen  2505 . An image is viewed from the side of the main body as an image projected on the screen  2505 . 
   The use of the invention disclosed in this specification makes it possible to provide a configuration of an active matrix type liquid crystal display integrated with a peripheral driving circuit in which the surface area excluding the region of a pixel matrix circuit is minimized. 
   Specifically, by employing a configuration in which a sealing material is provided on a peripheral driving circuit, the surface area excluding a pixel region can be minimized. Such a configuration further makes it possible to prevent damage to the peripheral driving circuit due to a pressure exerted by the sealing material. 
   The use of the invention disclosed in this specification makes it possible to prevent moisture from permeating into a thin film transistor circuit and to prevent a stress exerted on a liquid crystal panel from adversely affecting thin film transistors. 
   Specifically, a configuration can be obtained which prevents thin film transistors from being adversely affected by a stress exerted thereon during the fabrication and handling of s liquid crystal panel and prevents moisture from permeating into the liquid crystal panel. 
   It should be understood that the foregoing description is only illustrative of the invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the invention. Accordingly, the present invention is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims.

Technology Classification (CPC): 6