Abstract: A liquid crystal display device according to the present invention includes a first substrate, a second substrate, and a liquid crystal layer interposed between the first substrate and the second substrate. The first substrate includes: a plurality of gate lines; a plurality of source lines arranged to cross with the plurality of gate lines; a plurality of switching elements disposed in the vicinity of crossings of the plurality of gate lines and the plurality of source lines; and a plurality of pixel electrodes connected to the plurality of switching elements. The second substrate includes a counter electrode. A plurality of pixel regions are defined by the plurality of pixel electrodes, the counter electrode, and the liquid crystal layer interposed between the plurality of pixel electrodes and the counter electrode, and each of the plurality of pixel regions includes a reflection region and a transmission region.

Abstract: An electrode plate, suitable for constituting a liquid crystal device, includes at least a light-transmissive substrate, a plurality of metal electrodes disposed on the light-transmissive substrate and with spacings therebetween, and an insulating layer disposed at the spacings. Each of the metal electrodes includes a first layer, disposed on the light-transmissive substrate comprising a metal or alloy selected from the group consisting of titanium, chronium, molybdenum, tungsten, aluminum, tantalum and nickel, a second layer comprising copper or silver dispersed on the first layer; and a third layer comprising a metal or alloy selected from the group consisting of molybdenum, tantalum, tungsten, titanium, chromium, nickel, aluminum and zinc and disposed on the second layer.

Abstract: There are disclosed various types of TFT active matrix liquid crystal display devices and method of fabrication thereof in which a pixel is divided into three parts, a capacitor is added to each pixel, light shielding is applied to each TFT, and the matrix is driven by a DC cancelling technique.

Abstract: A liquid crystal panel includes bypass capacitors for removing a noise and a ripple from signals applied thereto. The liquid crystal panel is provided with a liquid crystal cell matrix having thin film transistors and liquid crystal cells arranged in a matrix pattern and located between the first and second glass substrates, and signal lines arranged on any one of the first and second glass substrates to receive signals from an exterior thereof. The bypass capacitors are formed and located in the lower portion of the signal lines and so as to be electrically connected to the signal lines. The bypass capacitors remove noise components included in the signals to be transferred through the signal lines.

Abstract: A manufacturing method of a liquid crystal display device including a step of:forming a first mask film; cleaning a surface of the first mask film with a brush; patterning the first mask film into a first mask layer comprising a cover pattern covering a first line pattern of the gate electrode and the gate electrode line, on the gate electrode and the gate electrode line; etching a defect portion in the first line pattern; and removing the first mask layer.

Abstract: A display device, in particular for a vehicle, has a viewing screen including a liquid crystal cell, the liquid crystal cell having a front cell wall and a rear cell wall and a liquid crystal substance arranged in the cell space between these cell walls, and with a heating device by means of which the display device can be heated. In order to ensure reliable operation of the display device even in the case of low temperatures, the heating device is arranged in the cell space of the liquid crystal cell directly or indirectly on the front cell wall and/or the rear cell wall.

Abstract: An electrode plate is formed by a substrate and a plurality of patterned electrodes formed on the substrate. Each patterned electrode has a laminate structure including a first layer of nickel metal formed on the substrate and a second layer of copper formed thereon. The electrode plate may be prepared by a process including a step of etching such a multilayer metal electrode-forming film formed on a substrate by spraying an etchant downwardly and uniformly onto the substrate while rotating the substrate at a rotation speed sufficient to allow quick liberation of the etchant from the substrate. The metal electrodes can be formed with a good adhesion onto the substrate and with good accuracies of width and thickness. By incorporating the electrode plate as a pair of substrates sandwiching a liquid crystal, a liquid crystal device showing free from transmission delay and rounding of voltage waveforms can be provided.

Abstract: A liquid crystal display includes a display region which is provided with a display pixel driving element, a drain driver which is arranged at least on a part around the display region for supplying a video signal to the display pixel driving element of the display region, a gate driver which is arranged at least on a part around the display region for supplying a scanning signal to the display pixel driving element of the display region, a drain line which is provided to connect the display region with the drain driver, and an additional capacitive electrode which is provided on a region between the display region and the drain driver.

Abstract: A spatial light modulator includes at least three picture elements, each of which includes a plurality of first elongate electrodes which are connected together and a plurality of second elongate electrodes which are connected together and which are interdigitated with the first electrodes. The first electrodes of a second of the picture elements are connected to the second electrodes of a first of the picture elements and the second electrodes of the second picture element are connected to the first electrodes of a third of the picture elements.

Abstract: Since Mo or MoW layer can be deposited so as to give low stress to the substrate by adjusting the deposition pressure, a single Mo or MoW layer can be used as a wiring by itself of large scale and high resolution liquid crystal. The Mo or MoW layer has the low resistivity of less than 15 .mu..OMEGA.cm and is etched to have a smooth taper angle using an Al etchant with Al or Al alloy. Therefore, it is possible to reduce the number of photolithography processes and to prevent a battery effect and generation of a hillock.

Abstract: A reflection-type liquid crystal display device includes a first substrate including a plurality of pixel electrodes arranged in a matrix and switching devices for driving the pixel electrodes. A second substrate includes a counter electrode, and a liquid crystal layer is interposed between the first substrate and the second substrate. The pixel electrodes each include a lower electrode layer and an upper electrode layer. The upper electrode layer is formed of either silver or a silver alloy and is reflective.

Abstract: A liquid crystal display (LCD) includes silicide-preventing regions between an amorphous silicon layer and source and drain regions. The silicide-preventing regions, which may be thin oxide regions, act as silicide barriers without degrading the contact resistance characteristics. The doped amorphous silicon layer and the amorphous layer may then be uniformly etched by reducing and preferably preventing the formation of silicide when forming the source and drain electrodes.

Abstract: In a semiconductor chip for Si chip based liquid crystal having insulating films and interconnection layers formed on a semiconductor substrate, a thin interconnection layer made of TiN/Ti having strong erosion resistance is formed on an uppermost interlayer insulating film having a flat surface to substantially expose the thin uppermost interconnection layer to the surface of the chip, the uppermost insulating film is covered with a protection film made of p-SiN and a thin insulating film having a mirror-like flat surface is formed on the uppermost interconnection layer.

Abstract: ITO transparent electrodes having a low surface resistivity of 20-70 .OMEGA./.quadrature. are formed on a glass substrate. An additional ITO transparent electrode having a high surface resistivity of about 1 M.OMEGA./.quadrature. is formed so as to cover the low-resistivity transparent electrodes. Locally generated high-voltage static electricity is distributed in the high-resistivity transparent electrode, to prevent a spark between adjacent low-resistivity electrodes.

Abstract: An electrode plate for a liquid crystal device is constituted by a light-transmissive substrate, a plurality of metal electrodes disposed on the light-transmissive substrate with a spacing therebetween, an insulating layer disposed at the spacing, and a plurality of transparent electrodes disposed on the insulating layer and each electrically connected with an associated metal electrode at a first end portion thereof. The first end portion of the transparent electrode is located closer to the light-transmissive substrate than an adjacent end portion of an adjacent transparent electrode. The electrode plate is effective in providing a liquid crystal device with a wider optical modulation region while improving image qualities.

Abstract: A liquid crystal display element comprising a light transmissive substrate (#34), insulating films (#52) formed on the substrate and transparent electrodes (#5) arranged to form predetermined patterns on the insulating films. Conductive lines (#51) are conductively in contact with the transparent electrodes, and each conductive line includes a first layer (#51a) made of indium tin oxide which is adhesive to the substrates. The conductive lines are arranged between the insulating films to form a plane surface with the insulating films.

Abstract: The liquid crystal display device comprises a first substrate, a second substrate opposite to the first substrate, a plurality of switching elements formed on a face of the first substrate, which is opposite to the second substrate, a common electrode formed on a face of the second substrate, the face being opposite to the first substrate, a plurality of liquid crystal layers stacked on the second substrate to hold the common electrode between the layers and the second substrate, and arranged between the first and second substrates a plurality of projection electrodes selectively formed on the liquid crystal layers and a plurality of pixel electrode each formed on a corresponding one of the liquid crystal layers. The pixel electrodes respectively formed between a corresponding couple of the liquid crystal layers are connected to a corresponding one of the switching elements formed on the first substrate through one or several of the protrusion electrode/electrodes.

Abstract: An active matrix substrate includes an insulative plate; a plurality of switching elements arranged in a matrix on the insulative plate; a plurality of gate signal lines for controlling the switching elements; a plurality of source signal lines for providing data signals to the switching elements, the source signal lines being perpendicular to the gate signal lines; and a plurality of pixel electrodes respectively provided above and in electric connection with drain electrodes of the switching elements. At least one of the source signal lines and the drain electrodes include at least a transparent conductive layer, a first metal layer and a second metal layer.

Abstract: Gate wire is formed on a transparent glass substrate, and a gate insulating film, an amorphous silicon layer, a doped amorphous silicon layer and Cr layer are deposited in sequence. After patterning the Cr layer, the doped amorphous silicon layer and the amorphous silicon layer, an ITO (indium-tin-oxide) layer is deposited and patterned, and then the exposed portions of the Cr layer and of the doped amorphous silicon layer are removed. A passivation film is deposited and patterned to form a plurality of contact holes over the ITO layer, and then a conductive layer is deposited and patterned to form a data line which is connected to the ITO layer through the contact holes.

Abstract: An array of pixel cells for a liquid crystal light value includes support pillars separating the array surface from a translucent top plate. During fabrication, a series of raised intersecting spacer walls having sides and a top surface are first formed by etching a thick oxide layer to stop on a nitride layer. Exposed nitride etch-stop layer is then removed, and electrode liner, metal electrode, and passivation layers are formed over the entire structure, including the sides and top surface of the spacer walls. Photoresist is then spun, hardened, and etched to expose the passivation formed over the tops of the spacer walls. The exposed passivation layer, and pixel liner and metal electrode material underneath the exposed passivation layer at the margins of the spacer walls are then etched. A photoresist mask is patterned to cover points of intersection of the spacer walls, and unmasked lengths of spacer walls are etched to stop on the nitride etch-stop layer.

Abstract: An array substrate includes plural scanning lines (111); a thin film transistor (112) having a first dielectric film (115), (117), a semiconductor film (120) thereon, and a source electrode (126b) electrically coupled to the semiconductor film (120) and a drain electrode (126a); a signal line (110) as taken out of the drain electrode (126a) to extend at substantially right angles to the scanning lines (111); and a pixel electrode (131) electrically connected to the source electrode (126b), wherein the pixel electrode (131) is electrically connected to the source electrode (126b) through a second dielectric film (127) as disposed on at least the signal line (110) while the pixel electrode (131) overlaps an elongate region (113) from its neighboring scanning line (111) through the first and second dielectric films (115), (117), (127).

Abstract: A thin film transistor of an active matrix liquid crystal display unit has a gate electrode continued to a gate terminal supplied with a gate control signal, a gate insulating layer formed beneath the gate electrode and the gate terminal, source and drain electrodes formed between the gate insulating layer and an insulating layer and an amorphous silicon layer extending on the insulating layer between the source and drain electrodes, and a silicide layer is inserted between the insulating layer and the gate insulating layer so as to enhance the adhesion therebetween.

Abstract: A liquid crystal display comprising: a transparent insulating substrate; a plurality of gate bus lines and a plurality of data bus lines arranged normal to the plurality of gate bus lines on the transparent insulating substrate, wherein a unit pixel region is defined by a region bounded by a pair of gate bus lines and a pair of data bus lines; a first electrode arranged parallel to the gate bus line within the unit pixel region; a first insulating layer formed on the first electrode; a second electrode formed at a selected portion of upper surface of the first insulating layer; a first transparent electrode formed within the unit pixel region, the first transparent electrode being apart by a selected distance from the second electrode, and being in contact with the first electrode; a second insulating layer formed on upper surface of the first insulating layer including the first transparent electrode and the second electrode; a second transparent electrode formed on the second insulating layer, the second tr

Abstract: A liquid crystal cell has a first substrate having a pixel electrode formed thereon, wherein the pixel electrode has a characteristic width; and a second substrate having a transparent conductive electrode layer formed thereon. Liquid crystal material is disposed between the pixel electrode and the transparent electrode layer. A wall of transparent conductive material projects from the transparent conductive electrode layer toward the liquid crystal material. The width of the wall is less than the characteristic width of the pixel electrode. The wall may comprise a transparent material layer formed on the second substrate and the transparent conductive electrode layer formed on the layer of transparent material. In the alternative, the wall may comprise a transparent conductive material layer formed on the transparent conductive electrode layer. The wall provides a lateral field that controls tilt direction of said liquid crystal material.

Abstract: A pair of common electrode lines are formed in the transverse direction, and a plurality of common electrodes in the longitudinal direction connect the common electrodes. Each pixel electrode parallel to the common electrodes is arranged between two of the common electrodes. A pair of connecting members which are connected to the pixel electrodes cover the edges of the common electrode lines adjacent the aperture region. Accordingly, since it is not necessary for a black matrix pattern formed in another substrate to shield the region where the liquid crystal direction does not properly behave, the black matrix lies outside the regions surrounded by the common electrodes, the pixel electrodes and the common electrode lines. In addition, the data line overlaps the adjacent common electrode, and thereby the aperture ratio is increased.

Abstract: A circuit plate, suitable for constituting an optical modulation device, such as a liquid crystal device, includes a light-transmissive substrate, and a plurality of principal electrodes and sub-electrodes supported on the light-transmissive substrate. Each sub-electrode is disposed between an associated principal electrode and the light-transmissive substrate so as to be electrically connected with the associated principal electrode. The plurality of sub-electrodes are disposed in a region in the light-transmissive substrate with gaps therebetween which are filled with an insulating layer, the sub-electrodes and the insulating layer in combination forming a surface on which the principal electrodes are formed. Further, a plurality of projection pieces are disposed in a region on the light-transmissive substrate outside the region of the sub-electrodes so as to be free from connection with the principal electrodes and the sub-electrodes.

Abstract: A liquid crystal display is described which includes a pair of transparent substrates disposed opposite each other sandwiching a liquid crystal layer therebetween, with a transparent electrode and an alignment film formed on the liquid crystal layer side of each of the substrates. The transparent electrodes disposed opposite each other in pairs are at two or more different spacings at least within one display area of a pixel.

Abstract: There are disclosed various types of TFT active matrix liquid crystal display devices in which a pixel is divided into three parts, a capacitor is added to each pixel, light shielding is applied to each TFT, and the matrix is driven by a DC cancelling technique.

Abstract: An array substrate includes plural scanning lines (111); a thin film transistor (112) having a first dielectric film (115), (117), a semiconductor film (120) thereon, and a source electrode (126b) electrically coupled to the semiconductor film (120) and a drain electrode (126a); a signal line (110) as taken out of the drain electrode (126a) to extend at substantially right angles to the scanning lines (111); and a pixel electrode (131) electrically connected to the source electrode (126b), wherein the pixel electrode (131) is electrically connected to the source electrode (126b) through a second dielectric film (127) as disposed on at least the signal line (110) while the pixel electrode (131) overlaps an elongate region (113) from its neighboring scanning line (111) through the first and second dielectric films (115), (117), (127).

Abstract: A liquid crystal display unit in which at least one of a gate electrode line, a drain electrode line, and a gate electrode and a source/drain electrode of a TFT formed on a substrate is composed of a metal Nb or an alloy material of Nb. Glass is used as the substrate, and the size thereof is preferably 300 mm or longer on one side and 1 mm or less in thickness. In order to provide a low wiring resistance to produce a high resolution and large size TFT panel, the resistivity of the metal Nb or the alloy material thereof is preferably 25 .mu..OMEGA.cm or less, and the film stress of Nb or the alloy material thereof on the glass substrate is 400 MPa or less.

Abstract: A method for fabricating a liquid crystal display is disclosed whereby a source and gate are exposed after the step of forming a passivation layer. As a result, the number of processing steps is reduced and yield is improved.

Abstract: A liquid crystal display device comprising a substrate; a first metal layer including an aluminum alloy having a first refractory metal with a first melting temperature over the substrate; and a second metal layer including a pure aluminum or an aluminum alloy having a second refractory metal with a second melting temperature lower than the first melting temperature over the first metal layer. The above liquid crystal display device of the present invention prevents the occurrence of hillocks on the aluminum gate metal. A method of manufacturing a liquid crystal display device is disclosed including the steps of forming a first metal layer of an aluminum alloy including a refractory metal having a first melting temperature on a substrate; and forming a second metal layer of a pure aluminum or an aluminum alloy including a refractory metal having a second melting temperature lower than the first melting temperature on the first metal layer.

Abstract: A TFT array having an improved aperture ratio with significantly increasing capacitive coupling between the pixel electrode and the drain bus line is disclosed. The TFT array includes a plurality of data bus line segments interconnected by the source electrode metallization. Further, a plurality of insulating layers are provided on the substrate to increase the separation between the pixel electrodes and the data bus lines.

Abstract: The present invention intends to provide an electrode substrate having at least a transparent electrode and a metal electrode provided on a transparent substrate, in which the metal electrode is formed on the transparent substrate through a dielectric layer having an irregular surface. The present invention further intends to provide a liquid crystal device having the electrode substrate, and methods for producing them. According to such a structure, the reflection of the outside light at the surface of the metal electrode can be prevented. Further, the electrode substrate can be readily produced.

Abstract: A liquid crystal display device incorporating an active matrix substrate having an inter-layer insulating film between a pixel electrode and gate and source signal lines. In this liquid crystal display device, the source signal line has a double-layer structure of an upper-layer line and a lower-layer line, but the upper-layer line is eliminated at the intersection of the gate signal line and the source signal line. This structure prevents a decrease in the thickness of the inter-layer insulating layer on the intersection of the gate signal line and the source signal line.

Abstract: A reflective liquid crystal cell for AMLCDs is provided wherein the reflective electrode may be passivated with an insulating film such as silicon oxide. In addition, the liquid crystal cell of the present invention may include a conducting transparent electrode that has a work function substantially equal to the work function of the reflective electrode in the cell. The reflective electrode may include a transparent conductive layer such as ITO, or may include an integer number of film pairs, wherein the film pair comprises a first dielectric film having a low index of refraction and a second dielectric film having a high index of refraction.

Abstract: An active matrix liquid crystal display comprises a first substrate, a second substrate, and liquid crystal held therebetween. The first substrate includes on one surface, a plurality of gate lines, a plurality of drain lines crossing the gate lines, and transistors each disposed in the vicinity of crossing points between the gate lines and the drain lines. Source electrodes of the transistors are each connected to pixel electrodes each disposed in the vicinity of the source electrodes. The drain electrodes of the transistors are connected to one of a plurality of the drain lines while the gate electrodes of the transistors are connected to one of a plurality of the gate lines. The second substrate is disposed in such a manner as to face to the first substrate and to have facing electrodes on the surface facing to the pixel electrodes.

Abstract: A method for forming a liquid crystal display includes the steps of depositing a first metal layer on a substrate, and depositing a second metal layer on the first metal layer opposite the substrate. The first and second metal layers are patterned to provide a gate electrode on a TFT area of the substrate and to provide a gate pad on a pad area of the substrate. An insulating layer is formed on the gate electrode and on the gate pad, and on the substrate, and a semiconductor layer is formed on the insulating layer opposite the gate electrode wherein the semiconductor layer includes a channel region opposite the gate electrode and first and second spaced apart source/drain regions separated by the channel region.

Abstract: A thin film transistor matrix device is fabricated by forming a transparent conductor film and a metal film on an insulating substrate in this order. The metal film and the transparent conductor film are together patterned to form picture element electrodes, and drain bus lines or gate bus lines. Source electrodes and drain electrodes may also be formed from the transparent conductor film and metal film. A semiconductor layer, an insulating film and a conductor film may be formed on the entire surface in this order. In this case, the conductor film, the insulator film and the semiconductor layer are patterned to form an active layer from the semiconductor layer, gate insulating films from the insulating film, and gate electrodes and gate bus lines from the conductor film. By patterning the conductor film, the insulating film and the semiconductor layer, the metal film of the picture element electrodes and drain bus lines is exposed.

Abstract: An electrode substrate is produced through at least the following steps of: forming a plurality of first electrodes on a light-transmissive substrate while leaving a spacing between the first electrodes, filling a resin in the spacing, curing the filled resin, and forming a plurality of second electrodes on the first electrodes and the resin so as to be in contact with the associated first electrodes, respectively. In the electrode substrate, the first electrodes have a thickness h (nm) and an average surface roughness d (nm) and the resin has a curing shrinkage ratio .alpha. (%). The thickness h, the average surface roughness d and the curing shrinkage ratio a satisfies the following relationship: d.gtoreq..alpha..multidot.h/1000.

Abstract: A liquid crystal display apparatus includes: a liquid crystal layer; a first substrate and a second substrate interposing the liquid crystal layer therebetween; a pixel electrode and a counter electrode respectively provided on opposing faces of the first substrate and the second substrate for applying a voltage to the liquid crystal layer; and a thin-film transistor provided on the first substrate and electrically connected to the pixel electrode, the thin-film transistor including a semiconductor layer having a source region and a drain region, wherein the pixel electrode is divided into a first sub-pixel electrode and a second sub-pixel electrode; parts of the first and second sub-pixel electrodes are overlapped via an insulating layer with each other; and at least one of the first and second sub-pixel electrodes is made of the same transparent material as a material for the semiconductor layer.

Abstract: An active-matrix substrate including a transparent insulative substrate, thin film transistors arranged in a matrix pattern on the transparent substrate, pixel electrodes each connected to a drain electrode of each of the thin film transistors, a plurality of gate lines each adapted to supply a signal to a gate electrode of each of the thin film transistors, a plurality of source signal lines intersecting the plurality of gate lines and each adapted to supply a signal to a source electrode of each of the thin film transistors, a shortcircuiting ring for shortcircuiting each of the signal lines at the periphery of the transparent insulative substrate, and a thin film resistor having a resistance of 10 k.OMEGA. to 500 k.OMEGA. provided intermediate between an input terminal of each of the signal lines and the shortcircuiting ring.

Abstract: An improved liquid crystal display(LCD) and a manufacturing method thereof capable of advantageously reducing point defects caused due to the defects of the thin film transistor and of increasing an aperture ratio by providing an upper and lower structure of a pixel electrode, which includes a plurality of transparent conductive film used as a pixel electrode and being vertically formed; and at least one thin film transistor being electrically connected to each of transparent conductive films.

Abstract: A liquid crystal display device is constituted by a pair of oppositely disposed substrates each having a plurality of opposing electrodes, and a ferroelectric liquid crystal disposed between the substrates so as to form a plurality of pixels each composed by a combination of a pair of the opposing electrodes and the ferroelectric liquid crystal disposed therebetween. Each pixel is provided with regions of different polarity inversion threshold voltages, and at least one of the pair of opposing electrodes is provided with a plurality of regions having unevennesses at different densities including a region with a higher density of unevennesses corresponding to a region of a lower polarity inversion threshold voltage and a region with a lower density of unevennesses corresponding to a region of a higher polarity inversion threshold voltage.