JP3677969B2 - Liquid crystal display panel driving device, liquid crystal display device, and electronic apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention belongs to the technical field of liquid crystal display panel driving devices, liquid crystal display devices, and electronic equipment, and in particular, active using two-terminal nonlinear elements having bidirectional diode characteristics such as MIM (Metal Insulator Metal) driving elements. The present invention belongs to a technical field of a matrix driving type liquid crystal display panel driving device, a liquid crystal display device (liquid crystal display module) including the driving device, and an electronic apparatus including the liquid crystal display device.
[0002]
[Prior art]
Conventionally, as an active matrix liquid crystal display panel, there is a liquid crystal display panel using a two-terminal type non-linear element having bidirectional diode characteristics such as an MIM driving element in addition to a TFT (thin film transistor) driving element. MIM driving elements and the like have steep thresholds, and are therefore advantageous in that there are fewer problems of crosstalk between pixels compared to the conventional simple matrix driving system. Compared to TFT driving elements, the element configuration and manufacturing process are advantageous. Is advantageous in that it is relatively simple.
[0003]
The basic principle of gradation display in a liquid crystal display panel using this type of MIM driving element will be described here. As shown in FIG. 20, on the other hand, a scanning line connected to each pixel electrode via the MIM driving element has a predetermined voltage value lower than the width defining the selection period and the threshold voltage of the MIM driving element. A pulsed scanning signal VS having (peak value) is supplied. On the other hand, in this selection period, a data signal VD composed of a pulse having a predetermined voltage value (crest value) is supplied to a data line (counter electrode) opposed to the pixel electrode with the liquid crystal interposed therebetween. At this time, if the difference between these voltage values (VS−VD) within the selection period is set so as to exceed the threshold voltage of the MIM drive element, the MIM drive element is only in the pixel to which both are supplied. It is turned on. As a result, a voltage is charged between the pixel electrode and the data line (counter electrode) across the liquid crystal, that is, an applied voltage is applied to the liquid crystal. Here, in particular, in the range of the voltage value sufficient to turn on the MIM driving element in cooperation with the scanning signal VS, as shown in FIG. 20, for example, the data signal VD1 as the voltage value VD1 → VD2. If the voltage value of the pulse forming the above is changed (that is, amplitude modulation), the applied voltage changes. As a result, the transmittance of the liquid crystal display panel changes according to the change of the applied voltage, and gradation display is performed.
[0004]
The above is the basic principle of gradation display by amplitude modulation of the data signal. However, in the case of an actual driving circuit, the scanning signal and the data signal have polarities for each field in order to drive the liquid crystal with AC. In order to invert and further prevent flicker, a method in which the polarity of the data signal is inverted every selection period is generally used. Accordingly, the data signal includes binary signals of + VD and −VD as shown in FIG. 21 including the pulse shown in FIG. In addition, in order to stably perform such a driving method, a positive bias voltage is applied to the scanning signal after a positive voltage pulse, and a negative bias voltage is applied to the scanning signal after a negative voltage pulse. The method is adopted.
[0005]
Data signal drive circuits that perform amplitude modulation of a data signal in this way include, for example, an analog type that generates a data signal from an analog RGB signal and a digital type that generates a data signal from a digital RGB signal, for example. .
[0006]
An analog data signal drive circuit can input analog video information in the same format as a conventional CRT to the drive circuit and directly process it. The number of necessary input lines is small, and a CRT (Cathode Ray Tube) is a liquid crystal. There are advantages such as easy replacement with a display panel. On the other hand, a digital data signal driving circuit can input digital video information corresponding to multimedia to the driving circuit directly without performing digital-analog conversion, and can be directly processed, resulting from deterioration during transmission of video information. There are advantages such as that the accuracy of the data signal does not decrease and that the signal deterioration accompanying the digital-analog conversion can be prevented in advance.
[0007]
[Problems to be solved by the invention]
In particular, an active matrix liquid crystal display panel using an MIM drive element has a unique advantage of a relatively simple device configuration and manufacturing process while increasing the number of gradations and realizing a high-quality image display. There is a general request to realize cost reduction by utilizing the above.
[0008]
However, the above-described conventional technique has the following problems.
[0009]
First, according to the above-described analog data signal driving circuit, it is not easy to control the amplitude of the data signal so as to faithfully reproduce the input infinite gradation video information. In other words, in order to display a high-quality image with multiple gradations, it is necessary to simply increase the accuracy of voltage control for each data signal, and a data signal driving circuit having excellent output voltage accuracy and operating speed is required. . Further, in this type of liquid crystal display panel, a so-called line-sequential time-division driving method in which a data signal for one row is simultaneously supplied to a plurality of scanning lines at the timing of a scanning pulse supplied to one scanning line is common. However, according to the analog data signal driving circuit described above, a liquid crystal display panel with a large number of pixels cannot be driven due to the frequency characteristics of the sample and hold circuit as a general component. Furthermore, when a digital video signal compatible with multimedia is displayed on the liquid crystal display panel, the burden of necessary digital-analog conversion increases as the number of gradations increases.
[0010]
On the other hand, according to the above-described digital data signal driving circuit, for example, when gradation display is performed with 256 gradations for each color of RGB (that is, a digital RGB signal of 24 bits in total for each color of 8 bits), When the multi-layer development is performed in order to lower the driving frequency, the data line must be driven with an accuracy of about 10 mV in which a voltage in the range of several volts is assigned to 256 gradations. Further, for example, in the case of performing gradation display with a 3-bit 8-gradation digital signal for one color, the required voltage level is 16 (on the + side) in order to drive the liquid crystal as described above. 8 levels, 8 levels on the negative side). Further, for example, in the case of performing gradation display with 6 bits of 64 gradation digital signals for one color, the required voltage level is 64 (32 on the + side) in order to drive the liquid crystal as described above. Level, 32 levels on the negative side). As the number of bits of the digital signal increases in this way, the number of required voltage levels increases exponentially. For example, a conventional voltage selection circuit composed of a resistance voltage dividing circuit and an analog switch is to cope with it. Have difficulty.
[0011]
As described above, whether it is an analog data signal driving circuit or a digital data signal driving circuit, the required voltage output accuracy and operation as long as the conventional method controls the gradation level by controlling the amplitude of the data signal. Speed is difficult to achieve with current integrated circuit technology.
[0012]
In a liquid crystal display panel using an MIM drive element or the like, as a method for performing gradation display, for example, a time ratio of taking a binary value of a data signal during one selection period, such as PWM (pulse width modulation), is used. It is not unthinkable to use a method that is controlled according to the gradation level. However, in this method, since the potential difference between the scanning signal VS and the data signal VD while the MIM driving element is turned on is constant, the liquid crystal is temporarily charged in each selection period until it is saturated. Therefore, gradation control cannot be performed at all. Therefore, during the charging of the liquid crystal via the MIM driving element (while the effective value of the applied voltage of the liquid crystal is increasing), the MIM driving element is switched from the on state to the off state. Therefore, it is expected that the switching point in time must be controlled in accordance with the difference in gradation level, and the apparatus configuration related to timing control and the like is fundamentally complicated and advanced.
[0013]
The present invention has been made in view of the above-described problems, and uses a two-terminal nonlinear element having bidirectional diode characteristics such as an MIM driving element that enables multi-gradation using a relatively simple configuration. It is an object of the present invention to provide a driving device for an active matrix driving type liquid crystal display panel, a liquid crystal display device including the driving device, and an electronic apparatus including the liquid crystal display device.
[0014]
[Means for Solving the Problems]
  In order to solve the above-described problem, the liquid crystal display panel driving device of the present invention includes a pair of first and second substrates, liquid crystal sandwiched between the first and second substrates, and the first substrate. A plurality of pixel electrodes provided in a matrix on the side facing the liquid crystal, a plurality of data lines arranged in a predetermined first direction on one of the first and second substrates, and the first and second substrates And a plurality of scanning lines arranged in a second direction intersecting the first direction and a plurality of data lines or scanning lines formed on the first substrate and the plurality of pixel electrodes, respectively. A liquid crystal display panel driving device comprising a plurality of two-terminal type non-linear elements each having a bidirectional diode characteristic, wherein a scanning signal comprising a pulse whose voltage value continuously increases or decreases within a selection period is scanned Scanning signal driving means for supplying to the line; While changing the width of the first period that takes the voltage value for turning on the two-terminal nonlinear element according to the difference between the voltage value of the pulse of the scanning signal within the selection period according to the gradation level of the display data, A data signal having a voltage value for turning off the two-terminal nonlinear element due to a difference from the voltage value of the pulse of the scanning signal in a second period excluding the first period within the selection period is applied to the data line. Data signal driving means for supplying the scanning signal driving means, wherein the scanning signal driving means changes the voltage value of the pulse in a non-linear manner so that the width of the first period is equidistant according to the gradation level. A signal is generated.
[0015]
  According to the driving device for the liquid crystal display panel, on the other hand, a scanning signal is generated by the scanning signal driving means and is supplied to a plurality of scanning lines at least for each row in a time division manner. On the other hand, a data signal is generated by the data signal driving means and supplied to a plurality of data lines at least for each column. Here, the scanning signal takes a voltage value for turning on the two-terminal nonlinear element in the first period in the selection period, and takes a voltage value for turning off the two-terminal nonlinear element in the second period, for example, It is a signal such as a pulse signal or a binary signal. Accordingly, only in the first period of the selection period, the two-terminal nonlinear element is turned on. In this first period, the scanning electrode or the counter electrode facing the pixel electrode and the liquid crystal sandwiched between the pixel electrode or the pixel electrode A voltage between the signal lines is applied to the liquid crystal as an applied voltage. Here, since the scanning signal is composed of pulses whose voltage value continuously increases or decreases, the voltage applied to the liquid crystal at the end of the first period is different if the width of the first period differs by ΔT. It differs by the amount of change in the scanning signal that increases or decreases during ΔT. When the first period ends and the second period is reached, the two-terminal nonlinear element is turned off, so that the voltage applied to the liquid crystal layer is the liquid crystal or the two-terminal nonlinear element in the off state. If the current flowing through is ignored, it is kept constant (that is, the voltage applied at the end of the first period). For example, this applied voltage is held until the two-terminal nonlinear element is turned on again in the next field. Accordingly, when the first period is changed (ie, modulated) for each field, for example, in accordance with the gradation level of the display data to be displayed on the pixel corresponding to the selection period by the data signal driving unit, the corresponding pixel is displayed. The applied voltage applied to the liquid crystal in each field varies from field to field in accordance with the gradation level. As a result, the transmittance of the liquid crystal display panel in the corresponding pixel changes, for example, for each field according to the gradation level, and gradation display on the liquid crystal display panel is performed according to the display data by the driving device.
[0016]
  In addition, the voltage value of the pulse forming the scanning signal changes nonlinearly so that the change in the first period becomes equal intervals according to the gradation level. Here, in general, in the liquid crystal display panel and its driving circuit, the transmittance of the liquid crystal display panel exhibits nonlinear characteristics with respect to the voltage value of the scanning signal. More specifically, even if the voltage value of the data signal is fixed and the voltage value of the scanning signal is changed at a certain rate under the condition that the two-terminal nonlinear element is turned on, the gradation in the liquid crystal The level does not change at a constant rate. Also in the present invention, for example, when the scanning signal is set to increase or decrease at a constant slope during the selection period, the change in the first period does not become equal intervals according to the gradation level. In this case, for example, the higher the gradation level, the smaller the change in the first period must be. However, in the invention of this claim, so that the change in the first period becomes an equal interval according to the gradation level, for example, when the scanning signal is composed of a pulse whose voltage value increases, the end of the first period is approached. The voltage value of this pulse is changed nonlinearly so that the increase rate becomes large. For this reason, even in a liquid crystal display panel and its driving circuit in which the transmittance of the liquid crystal display panel with respect to the voltage value of the scanning signal exhibits nonlinear characteristics, the change in the first period depends on the gradation level regardless of the nonlinear characteristics. Are equally spaced.
[0017]
  Further, the data signal driving means generates the data signal so as to take a voltage value to be turned off in a non-selection period excluding the selection period.
[0018]
  According to the driving device of the liquid crystal display panel, the data signal generated by the data signal driving unit takes a voltage value to be turned off during the non-selection period except the selection period. Therefore, since the two-terminal nonlinear element that is in the off state at the end of the second period in the selection period is in the off state even in the non-selection period, the applied voltage applied to the liquid crystal layer is If the current flowing through the two-terminal nonlinear element in the off state is ignored, it is kept constant. In the next field, this applied voltage is maintained until the two-terminal nonlinear element is turned on again.
[0019]
  Further, the scanning signal driving unit generates the scanning signal so that the voltage value of the pulse increases within the selection period, and the data signal driving unit sets the voltage value to be turned on and the off state. A binary data signal with a voltage value to be generated is generated.
[0020]
  According to the liquid crystal display panel driving device, a scanning signal is generated by the scanning signal driving means, and a binary data signal is generated by the data signal driving means, that is, a voltage value to be turned on and a voltage value to be turned off. Is done. Here, since the scanning signal is generated so that the voltage value of the pulse increases within the selection period, the voltage applied to the liquid crystal at the end of the first period is increased by ΔT in the width of the first period. For example, the change of the scanning signal that increases during ΔT (for example, α × ΔT if the rate of increase is a constant value α [voltage / time]). Therefore, when the first period is changed according to the gradation level of the display data by the data signal driving means, the applied voltage applied to the liquid crystal changes according to the gradation level.
[0021]
  Further, the difference at the end of the first period when the width of the first period is the minimum corresponds to a voltage at which the change in transmittance in the pixels of the liquid crystal display panel starts, and the width of the first period is the maximum. The scanning signal driving means and the data signal driving means respectively output the scanning signal and the data signal so that the difference at the end of the first period in the case corresponds to a voltage at which the transmittance is saturated. It is characterized by generating.
[0022]
  According to the liquid crystal display panel driving device, when the first period is minimized, the voltage difference at the end of the first period is the voltage at which the transmittance of the liquid crystal display panel starts changing (that is, the normally white mode). The voltage at which the gradation level is the lowest or the gradation level is the highest in the normally black mode). Therefore, the voltage applied to the liquid crystal is applied to the liquid crystal at the end of the first period, and until the next selection period in which the two-terminal nonlinear element is turned on. The voltage at which the transmittance change starts is held. When the first period is the maximum, the voltage difference at the end of the first period is the voltage at which the transmittance is saturated (that is, the gradation level is the highest in the normally white mode, or the gradation in the normally black mode. Equivalent to the voltage with the highest level). Therefore, the voltage applied to the liquid crystal is applied to the liquid crystal at the end of the first period, and until the next selection period in which the two-terminal nonlinear element is turned on. The voltage at which the transmittance is saturated is held.
[0023]
  Further, the scanning signal driving unit generates the scanning signal so that the voltage value of the pulse decreases within the selection period, and the data signal driving unit sets the voltage value to be turned on and the off state. Generating a binary data signal with a voltage value to be generated.
[0024]
  According to the liquid crystal display panel driving device, a scanning signal is generated by the scanning signal driving means, and a binary data signal is generated by the data signal driving means, that is, a voltage value to be turned on and a voltage value to be turned off. Is done. Here, since the scanning signal is generated so that the voltage value of the pulse decreases within the selection period, and the first period is provided in the second half of the selection period (TS), only the start time of the first period has two terminals. The type nonlinear element is turned on, and the voltage applied at this moment is held until the end of the first period. Therefore, when the start point of the first period is changed according to the gradation level of the display data by the data signal driving means, the applied voltage applied to the liquid crystal changes according to the gradation level.
[0025]
  According to another aspect of the present invention, there is provided a driving device for a liquid crystal display panel, wherein a pair of first and second substrates, liquid crystal sandwiched between the first and second substrates, and the first substrate are solved. A plurality of pixel electrodes provided in a matrix on the side facing the liquid crystal, a plurality of data lines arranged in a predetermined first direction on one of the first and second substrates, and the first and first A plurality of scanning lines arranged in the second direction intersecting the first direction on the other of the two substrates and a plurality of data lines or scanning lines formed on the first substrate and the plurality of pixel electrodes, respectively. An apparatus for driving a liquid crystal display panel comprising a plurality of two-terminal type non-linear elements having intervening bidirectional diode characteristics, wherein a scanning signal comprising pulses whose voltage value continuously decreases within a selection period is scanned Scanning signal driving means for supplying to the line; and While changing the width of the first period that takes the voltage value for turning on the two-terminal nonlinear element according to the difference between the voltage value of the pulse of the scanning signal within the selection period according to the gradation level of the display data, A data signal having a voltage value for turning off the two-terminal nonlinear element due to a difference from the voltage value of the pulse of the scanning signal in a second period excluding the first period within the selection period is applied to the data line. And a data signal driving means to be supplied.
[0026]
  According to the liquid crystal display panel driving device, a scanning signal is generated by the scanning signal driving means, and a data signal having a voltage value to be turned on and a voltage value to be turned off is generated by the data signal driving means. Here, since the scanning signal is generated so that the voltage value of the pulse decreases within the selection period, and the first period is provided in the second half of the selection period (TS), only the start time of the first period has two terminals. The type nonlinear element is turned on, and the voltage applied at this moment is held until the end of the first period. Therefore, when the start point of the first period is changed according to the gradation level of the display data by the data signal driving means, the applied voltage applied to the liquid crystal changes according to the gradation level.
[0027]
  Further, the difference at the start time of the first period when the first period changed by the data signal driving means is maximized is a voltage at which the change of the transmittance of the liquid crystal display panel in the corresponding pixel starts. The scanning signal driving means so that the difference at the start of the first period when the first period changed by the data signal driving means is minimum corresponds to a voltage at which the transmittance is saturated. The data signal driving means generates the scanning signal and the data signal, respectively.
[0028]
  According to the liquid crystal display panel driving device, when the first period is the maximum, the voltage difference at the start of the first period is the voltage at which the transmittance of the liquid crystal display panel starts to change (ie, normally white mode). The voltage at which the gradation level is the lowest or the gradation level is the highest in the normally black mode). Therefore, it is turned on only at the beginning of the first period, the voltage difference at that time is applied to the liquid crystal, and then applied to the liquid crystal until the next selection period in which the two-terminal nonlinear element is turned on. The applied voltage is held at a voltage at which the change in transmittance of the liquid crystal display panel starts. When the first period is minimum, the voltage difference at the start of the first period is a voltage at which the transmittance is saturated (that is, the gradation level is maximized in the normally white mode, or the gradation in the normally black mode. Corresponds to the voltage with the lowest level). Therefore, it is turned on only at the beginning of the first period, the voltage difference at that time is applied to the liquid crystal, and then applied to the liquid crystal until the next selection period in which the two-terminal nonlinear element is turned on. The applied voltage is held at a voltage at which the transmittance of the liquid crystal display panel is saturated.
[0029]
  In the liquid crystal display panel driving device, the scanning signal driving means generates the scanning signal including a predetermined bias voltage in a non-selection period excluding the selection period.
[0030]
  According to the liquid crystal display panel driving apparatus, the scanning signal driving means causes the positive bias voltage after the positive voltage value pulse or the negative bias after the negative voltage value pulse in the non-selection period. As a voltage, a scanning signal including a predetermined bias voltage is generated. Since the bias voltage is applied, the range of values that can be taken by the voltage value for turning on and off the two-terminal nonlinear element in the data signal is widened.
[0031]
  According to another aspect of the present invention, there is provided a liquid crystal display device comprising the liquid crystal display panel driving device and the liquid crystal display panel.
[0032]
  According to the above-mentioned liquid crystal display device (liquid crystal display module), the liquid crystal display panel is provided with a two-terminal type non-linear element in particular. Gray scale display is possible.
[0033]
  According to another aspect of the present invention, there is provided an electronic apparatus including the above-described liquid crystal display device in order to solve the above problems.
According to the electronic apparatus of the present invention, the electronic apparatus includes the above-described liquid crystal display device of the present invention, and the apparatus as a whole can perform multi-gradation display with a relatively simple configuration.
[0034]
Such an operation and other advantages of the present invention will become apparent from the embodiments described below.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0036]
(MIM drive element)
FIG. 1 is a plan view schematically showing an MIM driving element as an example of a two-terminal nonlinear element provided in a liquid crystal display panel according to an embodiment of the present invention, together with a pixel electrode. It is AA sectional drawing.
[0037]
1 and 2, the MIM driving element 20 is formed on an insulating film 31 formed on an MIM array substrate 30 constituting an example of the first substrate, and is formed on the insulating film 31 side. The first metal film 22, the insulating layer 24, and the second metal film 26 are sequentially formed to have an MIM structure (Metal Insulator Metal structure). The first metal film 22 of the two-terminal type MIM driving element 20 is connected to the scanning line 12 formed on the MIM array substrate 30 as one terminal, and the second metal film 26 is connected to the other terminal. Connected to the pixel electrode 34. In place of the scanning line 12, a data line (see FIG. 4) may be formed on the MIM array substrate 30 and connected to the pixel electrode. The second metal film 26 may be the same as the pixel electrode 34 or may be provided in the same shape.
[0038]
The MIM array substrate 30 is made of an insulating and transparent substrate such as glass or plastic. The insulating film 31 that forms the base is made of, for example, tantalum oxide. The insulating film 31 is formed for the purpose of preventing the first metal film 22 from being peeled off by the heat treatment after the formation of the second metal film 26 and preventing diffusion of impurities from the substrate 30 to the first metal film 22. Therefore, it is not always necessary if these are not problems. The first metal film 22 is made of a conductive metal thin film, for example, tantalum alone or a tantalum alloy. Alternatively, tantalum alone or a tantalum alloy as a main component may be added with elements such as tungsten and chromium. The insulating film 24 is made of, for example, an oxide film formed by anodic oxidation on the surface of the first metal film 22 in the chemical liquid. The second metal film 26 is made of a conductive metal thin film, for example, chromium alone or a chromium alloy. The pixel electrode 34 is made of a transparent conductive film such as an ITO (Indium Tin Oxide) film.
[0039]
FIG. 3 shows current-voltage characteristics of the MIM driving element 20 configured as described above.
[0040]
As is apparent from FIG. 3, the MIM driving element has nonlinear current-voltage characteristics, is almost symmetrical in both directions, and has steep threshold values at the voltage values of Vth and −Vth, respectively. Have. That is, the MIM driving element is in an off state (that is, a high resistance state) between the threshold voltages Vth and −Vth, and is on (low) when the threshold voltages Vth and −Vth are exceeded to the + side or the − side. Resistance state). Therefore, from these viewpoints, it is suitable as a switching element for the liquid crystal display panel.
[0041]
Although an MIM driving element has been described as an example of a two-terminal nonlinear element, a switching element such as a ZnO (zinc oxide) varistor, an MSI (Metal Semi-Insulator) driving element, or an RD (Ring Diode) is also used in this embodiment. The liquid crystal display panel can be used.
[0042]
(LCD panel)
Next, an active matrix liquid crystal display panel using the above-described MIM driving element 20 will be described with reference to FIGS. 4 is an equivalent circuit diagram showing the liquid crystal display panel together with the drive circuit, FIG. 5 is a partially broken perspective view schematically showing the liquid crystal display panel, and FIG. 6 is an applied voltage of the liquid crystal display panel. It is a graph which shows the transmittance | permeability characteristic with respect to.
[0043]
4, the liquid crystal display panel 10 includes a plurality of scanning lines 12 arranged on the MIM array substrate 30 connected to the scanning signal driving circuit 100, and a plurality of scanning lines 12 arranged on the counter substrate and also functioning as counter electrodes. The data line 14 is connected to the data signal driving circuit 110. The scanning signal driving circuit 100 and the data signal driving circuit 110 may be formed on the MIM array substrate 30 shown in FIGS. 1 and 2 or the counter substrate thereof. In this case, the scanning signal driving circuit 100 and the data signal driving circuit 110 include the driving circuit. A liquid crystal display device (liquid crystal display panel) is obtained. Alternatively, the scanning signal driving circuit 100 and the data signal driving circuit 110 may be configured by an IC independent of the liquid crystal display panel, and may be connected to the scanning lines 12 and the data lines 14 via predetermined wirings. The liquid crystal display device (liquid crystal display module) does not include a drive circuit.
[0044]
In each pixel region 16, the scanning line 12 is connected to one terminal of the MIM driving element 20 (see FIG. 1), and the data line 14 is connected to the liquid crystal layer 18 and the pixel electrode 34 shown in FIG. The other terminal of the MIM driving element 20 is connected. Accordingly, when a scanning signal is supplied to the scanning line 12 corresponding to each pixel region 16 and a data signal is supplied to the data line 14, the MIM driving element 20 in the pixel region is turned on (that is, a low resistance state). A drive voltage is applied to the liquid crystal layer 18 between the pixel electrode 34 and the data line 14 as the counter electrode via the MIM drive element 20.
[0045]
The LSI including the scanning signal driving circuit 100 and the data signal driving circuit 110 mounted by the TAB (tape automated bonding) method is scanned through an anisotropic conductive film provided in the peripheral portion of the MIM array substrate 30. If the structure which connects the line 12 and the data line 14 is taken, manufacture of the liquid crystal display panel 10 will become easier, and the flexibility in an apparatus structure will also increase. Further, if a configuration in which an LSI including the scanning signal driving circuit 100 and the data signal driving circuit 110 is mounted on the MIM array substrate 30 and the counter substrate 32 by a COG (chip on glass) method, the liquid crystal display panel 10 can be manufactured. Further, it becomes easier and the reliability is improved, and the configuration of the apparatus is simplified and the embeddability is enhanced.
[0046]
In FIG. 5, the liquid crystal display panel 10 includes an MIM array substrate 30 and a counter substrate 32 that constitutes an example of a transparent second substrate disposed to face the MIM array substrate 30. The counter substrate 32 is made of, for example, a glass substrate. The MIM array substrate 30 is provided with a plurality of transparent pixel electrodes 34 in a matrix. The plurality of pixel electrodes 34 extend along a predetermined X direction, and are connected to the plurality of scanning lines 12 arranged in the Y direction orthogonal to the X direction via the MIM driving element 20. An alignment film made of an organic thin film such as a polyimide thin film and subjected to a predetermined alignment process such as a rubbing process is provided on the side facing the liquid crystal such as the pixel electrode 34, the MIM driving element 20, and the scanning line 12. .
[0047]
On the other hand, the counter substrate 32 is provided with a plurality of data lines 14 extending in the Y direction and arranged in a strip shape in the X direction. The data line 14 also includes a portion as a counter electrode disposed to face the pixel electrode 34 with the liquid crystal layer 18 interposed therebetween. An alignment film made of an organic thin film such as a polyimide thin film and subjected to a predetermined alignment process such as a rubbing process is provided below the data line 14. The data line 14 is formed of a transparent conductive film such as an ITO film at least as a portion as the counter electrode. However, when the scanning line 12 is formed on the counter substrate 32 instead of the data line 14, the scanning line 12 is formed in a strip shape from a transparent conductive film such as an ITO film so as to function as a counter electrode. The
[0048]
Depending on the application of the liquid crystal display panel 10, the counter substrate 32 may be provided with a color filter made of a color material film arranged in, for example, a stripe shape, a mosaic shape, or a triangle shape. A black matrix such as resin black in which carbon or titanium is dispersed in a photoresist may be provided.
[0049]
Between the MIM array substrate 30 and the counter substrate 32 configured as described above and arranged so that the pixel electrode 34 and the data line 14 face each other, a sealant disposed along the periphery of the counter substrate 32 is used. Liquid crystal is sealed in the enclosed space, and a liquid crystal layer 18 (see FIG. 4) is formed. The liquid crystal layer 18 adopts a predetermined alignment state by the alignment film described above in a state where the electric field from the pixel electrode 34 and the data line 14 is not applied. The liquid crystal layer 18 is made of, for example, a liquid crystal in which one kind or several kinds of nematic liquid crystals are mixed. The sealing agent is an adhesive for bonding the substrates 30 and 32 around them, and a spacer for mixing the distance between the substrates with a predetermined value is mixed therein.
[0050]
FIG. 6 is a graph showing an example of the transmittance characteristic with respect to the applied voltage (effective value) of the liquid crystal display panel 10 in the case of the normally white mode. The applied voltage is a voltage difference (VS−VD) between the scanning signal VS and the data signal VD supplied to the pixel electrode 34 and the data line 14 as the counter electrode via the MIM driving element 20 which is turned on. In actuality, however, a voltage slightly smaller than this voltage difference is applied to the liquid crystal as an effective value of the applied voltage due to the resistance of the MIM driving element 20, the scanning line 12, the data line 14 and the like connected in series with the liquid crystal. Is done. When the applied voltage is equal to or lower than VLCDmin, the liquid crystal portion in the pixel corresponding to the pixel electrode takes a predetermined alignment state that maximizes the transmittance. This state corresponds to the minimum gradation level (pure white). When the applied voltage exceeds VLCDmin, the alignment state of the liquid crystal in this pixel starts to change, and the transmittance decreases monotonously as the applied voltage increases. When the applied voltage reaches VLCDmax, the change in the alignment state of the liquid crystal in this pixel almost stops and the transmittance is saturated to its minimum value. This state corresponds to the maximum gradation level (true black). Therefore, if the applied voltage (effective value) is changed between VLCDmin and VLCDmax, the transmittance can be changed between the minimum value and the maximum value. As a result, the relationship between the applied voltage and the gradation level is obtained in advance, and based on this, the voltage difference (VS−VD) that gives the applied voltage (effective value) corresponding to the gradation level of the display data is obtained. If the scanning signal and the data signal are supplied as described above, the display data can be displayed.
[0051]
Next, the operation of the liquid crystal display panel configured as described above will be briefly described.
[0052]
In FIG. 4, as the scanning signal driving circuit 100 sends a pulse-shaped scanning signal having a predetermined waveform (described later) to the MIM driving element 20 in a line sequential manner, the data signal driving circuit 110 displays the display signal as described later. Binary data signals in which a period for taking a voltage value for turning on the MIM driving element 20 in the selection period (hereinafter referred to as an on-voltage application period) changes in accordance with the gradation level of Send at the same time. When the voltage is applied to the pixel electrode 34 and the data line 14 in this way, the MIM driving element 20 in which the alignment state of the liquid crystal layer 18 in the portion sandwiched between the pixel electrode 34 and the data line 14 is turned on is applied. The transmittance of this portion changes to the transmittance corresponding to the length of the on-voltage application period. In the normally white mode, the incident light cannot pass through the liquid crystal portion when the applied voltage is applied. In the normally black mode, the incident light does not pass through the applied voltage. The liquid crystal part is allowed to pass through, and light having a contrast corresponding to the display signal is emitted from the liquid crystal display panel 10 as a whole.
[0053]
(First Embodiment of Driving Circuit)
Next, the configuration and operation of the scanning signal driving circuit 100 and the data signal driving circuit 110 shown in FIG. 4 in the first embodiment will be described with reference to FIGS. FIG. 7 is a waveform diagram showing the waveforms of the scanning signal VS and the data signal VD for two adjacent fields. The application applied to the liquid crystal layer 18 between the pixel electrode 34 and the data line 14 (counter electrode). The voltage is indicated by the vertical width of the shaded area. 8 is a waveform diagram in the case where the on-voltage application period is made longer than in the case of FIG. 7, and FIG. 9 is a waveform diagram in the case where the on-voltage application period is made shorter than in the case of FIG. is there.
[0054]
As shown in the waveform diagram of FIG. 7, in the present embodiment, the scanning signal driving circuit 100 that constitutes an example of the scanning signal driving means has a width corresponding to the selection period TS and a voltage value in the nth field. Is configured to generate a scanning signal VS composed of continuously increasing pulses such as VS1 → VS2 → VS3.
[0055]
Further, the data signal driving circuit 110 constituting an example of the data signal driving means has a difference (VS − (− VD)) from the voltage value of the scanning signal VS in the ON voltage application period (T1 to T2) in the nth field. As a result, a voltage value (−VD) for turning on the MIM driving element 20 is obtained, and the voltage of the scanning signal VS in the off voltage application period (T2 to T3) excluding the on voltage application period (T1 to T2) within the selection period TS. A step-like binary data signal having a voltage value (+ VD) for turning off the MIM driving element 20 is generated by a difference from the value (VS − (+ VD)). In addition, in the nth field, the data signal drive circuit 110 generates the data signal VD so as to take a voltage value (+ VD) that turns off the MIM drive element 20 in the non-selection period except the selection period TS.
[0056]
In this case, specific voltage values of the scanning signal VS and the data signal VD are set as follows. That is, when the scanning signal VS has the minimum value VS1 and the data signal VD has the voltage value −VD in the ON voltage application period (T1 to T2), the terminal voltage applied to the MIM driving element 20 is less than the threshold value Vth. When the scanning signal VS in the off voltage application period (T2 to T3) has the maximum value VS3 and the data signal VD has the voltage value + VD, the terminal voltage applied to the MIM driving element 20 is the threshold value Vth. The voltage values VS1, VS2, VS3, and VD are set so as to be smaller. With this setting, the MIM drive element is turned on in the on-voltage application period (T1 to T2), and the MIM drive element is turned off in the off-voltage application period (T2 to T3).
[0057]
In particular, in each field, the data signal drive circuit 100 has an on-voltage application period (T1 to T2) in which a voltage value is set to turn on the MIM drive element 20 due to a difference from the voltage value of the scanning signal VS within the selection period TS. The display data is changed according to the gradation level of display data to be displayed on the pixels corresponding to the selection period TS.
[0058]
Then, the scanning signal driving circuit 100 inverts the scanning signal VS having the above waveform for each field and supplies it to each scanning line 12, and the data signal driving circuit 110 corresponding to this, the binary signal having the above waveform. The voltage (−VD) for turning on the MIM driving element 20 and the voltage (+ VD) for turning off the MIM driving element 20 in each data signal are inverted for each field (that is, the MIM driving element 20 is turned on in the (n + 1) th field). The voltage (+ VD) and the voltage (−VD) for turning off are supplied to each data line 14. In this way, the voltage polarities of the scanning signal VS and the data signal VD are inverted for each field in order to prevent the liquid crystal layer 18 from being deteriorated by AC driving the liquid crystal layer 18. Further, from the viewpoint of preventing flicker, the voltage polarity may be reversed for each of one or two scanning lines 12.
[0059]
According to the first embodiment of the scanning signal driving circuit 100 and the data signal driving circuit 110 configured as described above, the on-voltage application period (T1 to T2) starts in the selection period TS in the nth field. At time T1, the voltage difference (VS1-(− VD)) exceeds the threshold voltage Vth, so that the MIM driving element 20 is turned on. Accordingly, charging of the liquid crystal layer 18 between the pixel electrode 34 and the data line 14 (counter electrode) in the corresponding pixel is started. In this on-voltage application period (T1 to T2), the voltage value of the scanning signal VS increases monotonously as VS1 → VS2, so this voltage difference (VS − (− VD)) increases monotonously. Then, the liquid crystal layer 18 is continuously charged while the MIM driving element 20 is kept on. Therefore, in this on-voltage application period (T1 to T2), the applied voltage ΔV applied to the liquid crystal layer 18 increases with an increase in the scanning signal VS.
[0060]
As shown in FIG. 8, if the end time T2 of the on-voltage application period (T1 to T2) is delayed, that is, if the on-voltage application period (T1 to T2) is lengthened, the on-voltage application period (T1) The voltage ΔV applied to the liquid crystal layer 18 at the end time T2 of (˜T2) increases by the amount of change in the scanning signal VS that increases within the longer period. On the other hand, as shown in FIG. 9, if the end time T2 of the on-voltage application period (T1 to T2) is shortened, that is, if the on-voltage application period (T1 to T2) is shortened, the on-voltage application period (T1). The voltage ΔV applied to the liquid crystal layer 18 at the end time T2 of (˜T2) is decreased by the amount of change in the scanning signal VS that has increased within the shortened period.
[0061]
As shown in FIGS. 7 to 9, when the on-voltage application period (T1 to T2) ends and the off-voltage application period (T2 to T3) comes, the MIM driving element 20 is turned off, so that the liquid crystal layer The applied voltage ΔV applied to 18 is applied at a constant value, that is, at the end time T2 of the on-voltage application period (T1 to T2) if the current flowing through the liquid crystal layer 18 and the MIM driving element 20 in the off state is ignored. Maintained at a voltage value. Then, through the non-selection period, for example, until the MIM drive element 20 is turned on again in the next field, the applied voltage ΔV is held because the MIM drive element 20 is turned off.
[0062]
In this case, if the following expression (1) holds, the discharge through the MIM drive element 20 in the non-selection period can be ignored.
[0063]
VLCDmax + VD <Vth (1)
That is, the maximum voltage that can be applied to the MIM drive element 20 in the non-selection period is “VLCDmax + VD”. If this is smaller than the threshold value Vth of the MIM drive element 20, the MIM drive element The off state can be maintained in the non-selection period.
[0064]
Further, in the present embodiment, the voltage values VS1 and VS3 related to the scanning signal VS and the data signal VD are related so that the gradation level can be changed in the predetermined range by changing the applied voltage ΔV in the predetermined range. The relationship between the voltage value VD (−VD), the threshold voltage Vth of the MIM drive element 20, and the voltage values VLCDmax (corresponding to white display) and VLCDmin (corresponding to black display) related to the applied voltage (effective value) The following formulas (2) to (4) are set.
[0065]
VS1 + VD-Vth ≤ VLCDmin (2)
VS3 + VD-Vth ≥ VLCDmax (3)
VS3-VD -Vth ≤ VLCDmin (4)
Formula (2) is an applied voltage that is equal to or lower than the voltage value VLCDmin corresponding to white display when the ON voltage application period (T1 to T2) is modulated to be the shortest and the end time T2 is made coincident with the start time T1. Can be applied to the liquid crystal layer 18 (that is, the time point T2 corresponding to the applied voltage of the voltage value VLCDmin exists between the time point T1 and the time point T3).
[0066]
Equation (3) shows that when the on-voltage application period (T1 to T2) is modulated the longest and the end time T2 coincides with the end time T3, the applied voltage equal to or higher than the voltage value VLCDmax corresponding to black display Can be applied to the liquid crystal layer 18 (that is, the time point T2 corresponding to the applied voltage of the voltage value VLCDmax exists between the time point T1 and the time point T3).
[0067]
In the off voltage application period (T2 to T3), the expression (4) indicates that even when the highest voltage value VS3 of the scanning signal VS is supplied, the applied voltage is a voltage equal to or lower than the voltage VLCDmin corresponding to white display (that is, This means that the applied voltage applied during the off-voltage application period is small enough not to adversely affect the applied voltage ΔV even when the scanning signal VS takes the maximum value.
[0068]
As described above, since the MIM driving element 20 is turned on or off, the data signal driving circuit 110 displays display data to be displayed on the pixels corresponding to the selection period TS during the on-voltage application period (T1 to T2). When modulation is performed for each field according to the gray level, the applied voltage ΔV applied to the liquid crystal layer 18 in the corresponding pixel changes for each field according to the gray level. As a result, the transmittance in the corresponding pixel changes for each field in accordance with the gradation level, and gradation display on the liquid crystal display panel 10 is performed in accordance with the display data. For example, by using display data indicating an 8-bit gradation level as input, the end time T2 of the on-voltage application period (T1 to T2) is changed 256 times between T1 and T3, thereby increasing the number of 256 gradations. Gradation display is obtained on the liquid crystal display panel 10. In this case, if RGB color display is used, a multi-gradation display of 256 × 256 × 256 = 16.7 million colors is displayed on a frame image composed of three RGB fields. Is obtained.
[0069]
Next, a more specific configuration of the data signal driving circuit 110 that generates the data signal VD described above will be described with reference to FIGS.
[0070]
As shown in the block diagram of FIG. 10, the data signal drive circuit 110 includes an X counter 111, a GCP generation circuit 112, and an X driver circuit 113.
[0071]
For example, an 8-bit digital signal of D0 to D7 indicating one level of 256 gradation levels (gradation levels 0 to 255) is input to the data signal driving circuit 110 for each pixel. The synchronization signal HSYNC and the reference clock XCK for driving the X driver circuit 113 are input.
[0072]
The GCP generation circuit 112 includes, for example, 255 comparison circuits and a logical sum circuit that calculates a logical sum of these comparison results. The GCP generation circuit 112 is reset for each HSYNC and counted for each reference clock XCK. The count value of the X counter 111 to be increased is compared with 255 voltage values set based on the change width of the ON voltage application period (T1 to T2) with respect to the gradation level. Such a change width of the on-voltage application period depends on the characteristics of each liquid crystal display device, and the liquid crystal display device is determined in advance by experiment, theory, simulation, or the like.
[0073]
Then, by calculating the logical sum of the comparison results of these comparison circuits, as the calculation output, per selection period having a different interval corresponding to the change width of the ON voltage application period corresponding to 256 gradation levels. A GCP signal composed of a sequence of 255 pulses is generated. The GCP signal generated in this way is supplied to the GCP input terminal of the X driver circuit 113.
[0074]
For example, when an 8-bit input digital signal D0 to D7 having 256 gradations is input to the X driver circuit 113, the digital signal D0 to D7 is in one-to-one correspondence with the plurality of data lines 14 based on the reference clock XCK. Is held in a predetermined internal register. By sequentially transferring the X driver circuit 216 corresponding to the digital signals D0 to D7 to the internal register, all the digital signals for one horizontal line are held in the internal register. From the internal register, with the LP signal as a trigger, the ON voltage application period is an 8-bit digital value in the internal register according to the GCP signal composed of a sequence of 255 pulses per selection period input from the GCP generation circuit 112. A data signal VD whose voltage changes at the end time T2 is generated so as to have a width corresponding to the gradation level indicated by.
[0075]
As shown in FIG. 11, the GCP signal output from the GCP generation circuit 112 is composed of a sequence of 255 pulses per selection period indicated by the FR signal. In the X driver circuit 113, the end time T2 is set so that the ON voltage application period has a width corresponding to the gradation level “2” indicated by the 8-bit digital value in the internal register in accordance with the GCP signal. Thus, the data signal VD whose voltage changes from −VD to + VD is generated (see the middle stage of FIG. 11). Alternatively, for example, the data signal VD whose voltage changes from −VD to + VD is generated at the end time T2 so as to have a width corresponding to the gradation level “5” (see the lower part of FIG. 11).
[0076]
In the present embodiment, it is preferable that the on-voltage application period (T1 to T2) changed by the data signal driving circuit 100 is minimized, that is, T2 is closest to the T1 side or matched with T1. In this case, the voltage difference (VS − (− VD)) at the end time T2 corresponds to the voltage VLCDmim for starting the change in transmittance shown in FIG. 6, and the on-voltage application period (T1 to T2) is maximized. The voltage difference (VS − (− VD)) at the end point T2 when T2 is closest to T3 or coincides with T3 corresponds to the voltage VLCDmax at which the transmittance shown in FIG. 6 is saturated. Thus, the voltage values VS1, VS2, VS3, and VD of the scanning signal VS and the data signal VD are set. Therefore, multi-gradation display is performed using the entire range in which the transmittance of the liquid crystal display panel 10 changes. In addition, by modulating the on-voltage application period using the entire range of the selection period, it is possible to maximize the width of the change in the on-voltage application period corresponding to the change in one level of the gradation level. The frequency of the reference clock XCK for modulating the on-voltage application period in the data signal driving circuit 100 can be kept low.
[0077]
As described above in detail, according to the present embodiment, gradation display can be performed by modulating the on-voltage application period in the manner of pulse width modulation. In addition, a circuit for generating a large number of voltage levels and a circuit for controlling the switching of a large number of voltage levels are not required, and a multi-gradation can be achieved using the scanning signal driving circuit 100 and the data signal driving circuit 110 having a relatively simple configuration. Can display high-quality images.
[0078]
(Second Embodiment of Driving Circuit)
Next, the configuration and operation of the scan signal driving circuit 100 and the data signal driving circuit 110 shown in FIG. 4 in the second embodiment will be described with reference to FIG. FIG. 12 is a waveform diagram showing the waveforms of the scanning signal VD and the data signal VS for two adjacent fields.
[0079]
As shown in the signal waveform diagram of FIG. 12, in the present embodiment, unlike the case of the first embodiment, the scanning signal driving circuit 100 continuously decreases the voltage value as VS1 → VS2 → VS3. It is configured to generate a scanning signal VS composed of pulses to be transmitted.
[0080]
Further, the data signal driving circuit 110 generates the data signal VD obtained by inverting + VD and −VD around 0 V as in the first embodiment, and the on-voltage application period (T2 to T2) in the latter half of the selection period (TS). T3) is provided, and the applied voltage applied to the liquid crystal is changed by moving T2 as the start time.
[0081]
According to the second embodiment configured as described above, in the on-voltage application period (T2 to T3), the voltage value of the scanning signal VS monotonously decreases as VS2 → VS3. In the application period (T2 to T3), the MIM driving element 20 is actually turned on only for a moment at the start of T2, and the liquid crystal layer potential is VS2 + VD−Vth. Immediately thereafter, the voltage applied to the MIM driving element 20 continues to decrease monotonously, and thus continues to be in the off state. Therefore, the applied voltage ΔV applied to the liquid crystal layer in the on-voltage application period (T2 to T3) is determined at the start of T2.
[0082]
Here, if the start time T2 of the on-voltage application period (T2 to T3) is delayed, the applied voltage ΔV at the time when the MIM driving element 20 is turned on decreases, so that the transmission shown in FIG. The rate will approach the voltage VLCDmin at which the rate change begins. On the other hand, if the start time T2 of the on-voltage application period (T2 to T3) is made earlier, the applied voltage ΔV at the time when the MIM driving element 20 is turned on increases, so the transmittance shown in FIG. Approaches the voltage VLCDmax that saturates. Since the MIM drive element 20 is in an off state except for the start time of T2, the applied voltage ΔV is set to the voltage value applied at the start time T2 of the on-voltage application period, and the MIM drive element 20 in the next field. Holds until turned on.
[0083]
Therefore, also in the second embodiment, the data signal driving circuit 110 modulates the on-voltage application period for each field (by moving the start time T2) according to the gradation level of the display data. Then, the applied voltage ΔV is modulated according to the gradation level, and gradation display is performed.
[0084]
In the second embodiment, preferably, the voltage difference at the start time T2 when the on-voltage application period (T2 to T3) is minimum corresponds to the voltage VLCDmim, and the on-voltage application period (T2 to T3). The voltage values of the scanning signal VS and the data signal VD are set so that the voltage difference at the start time T2 when the maximum value corresponds to the voltage VLCDmax.
[0085]
(Third embodiment of drive circuit)
Next, the configuration and operation of the scanning signal driving circuit 100 and the data signal driving circuit 110 shown in FIG. 4 in the third embodiment will be described with reference to FIG. FIG. 13 is a waveform diagram showing the waveforms of the scanning signal VD and the data signal VS for two adjacent fields.
[0086]
As shown in the signal waveform diagram of FIG. 13, in this embodiment, unlike the case of the first embodiment, the scanning signal driving circuit 100 has an on-voltage application period (T1 to T2) corresponding to the gradation level. A scanning signal VS composed of pulses whose voltage values increase nonlinearly as VS1 → VS2 → VS3 is generated so that the change of is equal. For this reason, the scanning signal driving circuit 100 is particularly configured to include a waveform shaping circuit for shaping a pulse having such a waveform at a rectangular or monotonically increasing or decreasing pulse output stage.
[0087]
The data signal driving circuit 110 generates a data signal VD that is almost the same as that in the first embodiment. However, unlike the case of the first embodiment, the on-voltage application period is set according to the gradation level. It is configured to simply change at equal intervals.
[0088]
In general, in a liquid crystal display device, the transmittance of a liquid crystal display panel exhibits nonlinear characteristics with respect to the voltage value of a scanning signal. More specifically, even if the voltage value of the data signal is fixed and the voltage value of the scanning signal is changed at a certain rate under the condition that the MIM driving element is turned on, the gradation in the liquid crystal display panel The level does not change at a constant rate. Also in the case of the first embodiment, since the scanning signal VS is set to increase at a constant slope during the selection period TS, the change in the on-voltage application period does not become equal according to the gradation level. In this case, for example, using the GCP signal described above, the change width of the on-voltage application period must be gradually reduced as the gradation level increases. However, in this embodiment, the nonlinear characteristic of the transmittance with respect to the applied voltage in the liquid crystal display device is examined in advance, and the voltage change curve of the pulse of the scanning signal VS is set in accordance with this nonlinearity. By setting in this way, the change width of the on-voltage application period can be equally spaced according to the gradation level. For this reason, even in a liquid crystal display device in which the transmittance of the liquid crystal display panel with respect to the voltage value of the scanning signal VS exhibits nonlinear characteristics, the change width of the on-voltage application period depends on the gradation level regardless of the nonlinear characteristics. Evenly spaced.
[0089]
As a result, in the data signal driving circuit 110, the change width of the on-voltage application period can be easily controlled based on, for example, the GCP signal (see FIG. 11) composed of pulse trains at equal intervals.
[0090]
Also in the third embodiment, preferably, as in the first embodiment, the voltage difference at the end time T2 when the on-voltage application period is minimized corresponds to the voltage VLCDmim, and is turned on. The voltage values of the scanning signal VS and the data signal VD are set so that the voltage difference at the end time T2 when the voltage application period is maximum corresponds to the voltage VLCDmax.
[0091]
(Modified form of drive circuit)
In each of the embodiments described above, the ON voltage application period starts from T1 superimposed on the start time of the selection period TS and extends to an arbitrary time T2 in the selection period TS where the position changes according to the gradation level. Has been. However, the start time T1 of the on-voltage application period may be set to a time later by a certain time than the start time of the selection period TS. Further, the end time T3 of the on-voltage application period may be set to a time earlier by a certain time than the end time of the selection period TS.
[0092]
In each of the embodiments described above, the applied voltage is modulated by moving the end time T2 of the on-voltage application period back and forth according to the gradation level. However, the end time T2 of the on-voltage application period is fixed and the start time T1 is changed according to the gradation level, or both the start time T1 and the end time T2 are changed according to the gradation level. Thus, the applied voltage may be modulated by changing the length of the on-voltage application period.
[0093]
In each of the embodiments described above, the scanning signal and the data signal are synchronized at the timing when the ON voltage application period comes before the OFF voltage application period within the selection period. However, within the selection period, the scanning signal and the data signal may be synchronized at a timing when the off-voltage application period comes before the on-voltage application period.
[0094]
In each of the embodiments described above, the data signal VD is binary data that takes voltage values + VD and −VD. However, the data signal may be ternary data having a voltage value (crest value) + VD positive pulse and a voltage value −VD negative pulse with a voltage value of 0 V as a reference. Even in the case of binary data, there is no necessity that the binary values are + VD and -VD, and binary data of 0 V and + VD (or -VD) may be used. In any case, if the temporal and potential relationship between the scanning signal and the data signal as described in each embodiment is obtained, the same operation and effect as each embodiment can be obtained. It is done.
[0095]
In each of the embodiments described above, no bias voltage is applied to the scanning signal VS. However, as shown in FIG. 14, a bias voltage may be applied to the scanning signal VS. More specifically, in the non-selection period, for example, a + Vns bias voltage is applied after the + side pulse and a −Vns bias voltage is applied after the − side pulse. The scanning signal VS may be generated. In particular, when the bias voltage is applied in this way, it is required that the following expressions (5) and (6) be satisfied instead of the above-described expression (1).
[0096]
For the scanning signal VS consisting of a positive pulse:
(VLCDmax−Vns) + VD <Vth (5)
For the scanning signal VS consisting of a negative pulse:
(Vns-VLCDmin) + VD <Vth (6)
Therefore, by setting Vns to about (VLCDmax + VLCDmin) × ½, the range that the data signal VD can take is expanded, the margin is widened, and the design of the data signal driving circuit 100 is facilitated.
[0097]
As described above, as long as the scanning signal driving circuit 100 and the data signal driving circuit 110 have a configuration in which the period during which the scanning signal is increased or decreased is changed by changing the on-voltage application period within the selection period, various modifications may be used. The gradation control of the liquid crystal display panel 10 can be performed.
[0098]
When the liquid crystal display panel 10 described above is applied to, for example, a color liquid crystal projector, the three liquid crystal display panels 10 are used as RGB light valves, and each panel has a dichroic mirror for RGB color separation. Therefore, it is not necessary to provide a color filter on the counter substrate 32 because the light of each color separated through the light is incident as incident light. On the other hand, when the liquid crystal display panel 10 is applied to, for example, a direct-view or reflective color liquid crystal television, an RGB color filter is formed on a counter substrate 32 together with its protective film in a predetermined region facing the pixel electrode 34. It may be formed.
[0099]
In the liquid crystal display panel 10, a planarizing film is applied to the entire surface of the pixel electrode 34, the MIM driving element 20, the scanning line 12, etc. by spin coating or the like in order to suppress alignment defects of liquid crystal molecules on the MIM array substrate 30 side. Alternatively, a CMP process may be performed.
[0100]
In the above embodiment, gradation display is performed by modulating the on-voltage application period based on the so-called “four-value driving method”. It is also possible to perform gradation display in the same manner based on the charge / discharge driving method disclosed in Japanese Patent No. 125225.
[0101]
Further, in the liquid crystal display panel 10, the liquid crystal layer 18 is made of nematic liquid crystal as an example. However, if polymer dispersed liquid crystal in which liquid crystal is dispersed as fine particles in a polymer is used, the alignment film and polarizing film described above are used. Further, there is no need for a polarizing plate or the like, and the advantages of high brightness and low power consumption of the liquid crystal display panel can be obtained by increasing the light utilization efficiency. Further, by forming the pixel electrode 34 from a metal film having a high reflectance such as Al, when the liquid crystal display panel 10 is applied to a reflection type liquid crystal display device, the liquid crystal molecules are substantially vertically aligned in the state where no voltage is applied. Also, SH (super homeotropic) type liquid crystal may be used. Furthermore, in the liquid crystal display panel 10, the data line 14 is provided on the counter substrate 32 side so as to apply an electric field (vertical electric field) perpendicular to the liquid crystal layer, but an electric field (lateral electric field) parallel to the liquid crystal layer is provided. ) Is applied to each pixel electrode 34 from the pair of electrodes for generating the horizontal electric field (that is, the electrode for generating the vertical electric field is not provided on the counter substrate 32 side, and the MIM array substrate 30 side is provided). It is also possible to provide an electrode for generating a transverse electric field. Using a horizontal electric field in this way is more advantageous in widening the viewing angle than using a vertical electric field. In addition, the present embodiment can be applied to various liquid crystal materials (liquid crystal phases), operation modes, liquid crystal alignments, driving methods, and the like.
[0102]
(Electronics)
Next, an embodiment of an electronic device including the liquid crystal display panel 10, the scanning signal driving circuit 100, and the data signal driving circuit 110 described in detail above will be described with reference to FIGS.
[0103]
First, FIG. 15 shows a schematic configuration of an electronic apparatus including the liquid crystal display panel 10 and the like in this way.
[0104]
In FIG. 15, an electronic device includes a display information output source 1000, a display information processing circuit 1002, a driving circuit 1004 including the scanning signal driving circuit 100 and the data signal driving circuit 110, a liquid crystal display panel 10 and a clock generation circuit 1008. In addition, a power supply circuit 1010 is provided. The display information output source 1000 includes a ROM (Read Only Memory), a RAM (Random Access Memory), a memory such as an optical disk device, a tuning circuit, and the like. The display information is output to the display information processing circuit 1002. The display information processing circuit 1002 is configured to include various known processing circuits such as an amplification / polarity inversion circuit, a phase expansion circuit, a rotation circuit, a gamma correction circuit, and a clamp circuit, and display information input based on a clock. From the above, the 8-bit 256-gradation digital signal DATA (D0 to D7) is sequentially generated and output to the drive circuit 1004 together with the clock CLK. The driving circuit 1004 drives the liquid crystal display panel 10 by the scanning signal driving circuit 100 and the data signal driving circuit 110 by the driving method described above. The power supply circuit 1010 supplies predetermined power to the above-described circuits. Note that the drive circuit 1004 may be mounted on the MIM array substrate constituting the liquid crystal display panel 10, and in addition to this, the display information processing circuit 1002 may be mounted.
[0105]
Next, FIGS. 16 to 19 show specific examples of the electronic apparatus configured as described above.
[0106]
In FIG. 16, a liquid crystal projector 1100, which is an example of an electronic device, prepares three liquid crystal display modules including the liquid crystal display panel 10 in which the drive circuit 1004 described above is mounted on an MIM array substrate, and each of the RGB light valves 10R. It is configured as a projection type projector used as 10G and 10B. In the liquid crystal projector 1100, when projection light is emitted from the lamp unit 1102 of the white light source, light corresponding to the three primary colors of RGB is generated by the two dichroic mirrors 1108 through the plurality of mirrors 1106 inside the light guide 1104. Divided into components R, G, and B, they are led to light valves 10R, 10G, and 10B corresponding to the respective colors. The light components corresponding to the three primary colors modulated by the light valves 10R, 10G, and 10B are synthesized again by the dichroic prism 1112, and then projected as a color image on the screen or the like via the projection lens 1114.
[0107]
In FIG. 17, a laptop personal computer 1200, which is another example of an electronic device, includes the above-described liquid crystal display panel 10 in a top cover case, and further accommodates a CPU, a memory, a modem, and the like, and a keyboard 1202. Is incorporated in the main body 1204.
[0108]
In FIG. 18, a pager 1300 as another example of an electronic device includes a backlight 1306a in a liquid crystal display panel 10 in which the drive circuit 1004 described above is mounted on a MIM array substrate in a metal frame 1302 to form a liquid crystal display module. A light guide 1306, a circuit board 1308, first and second shield plates 1310 and 1312, two elastic conductors 1314 and 1316, and a film carrier tape 1318 are accommodated. In the case of this example, the display information processing circuit 1002 (see FIG. 15) described above may be mounted on the circuit board 1308 or on the MIM array substrate of the liquid crystal display panel 10. Further, the above-described drive circuit 1004 can be mounted on the circuit board 1308.
[0109]
Since the example shown in FIG. 18 is a pager, a circuit board 1308 and the like are provided. However, in the case of the liquid crystal display panel 10 in which the driving circuit 1004 and the display information processing circuit 1002 are mounted to form a liquid crystal display module, a liquid crystal display device in which the liquid crystal display panel 10 is fixed in a metal frame 1302 is used. In addition, a backlight type liquid crystal display device incorporating a light guide 1306 can be produced, sold, used, or the like.
[0110]
As shown in FIG. 19, in the case of the liquid crystal display panel 10 in which the driving circuit 1004 and the display information processing circuit 1002 are not mounted, an IC 1324 including the driving circuit 1004 and the display information processing circuit 1002 is mounted on the polyimide tape 1322. It is physically and electrically connected to a TCP (Tape Carrier Package) 1320 via an anisotropic conductive film provided on the periphery of the MIM array substrate 30 to produce, sell, use, etc. as a liquid crystal display device It is also possible.
[0111]
In addition to the electronic devices described above with reference to FIGS. 16 to 19, a liquid crystal television, viewfinder type or monitor direct-view type video tape recorder, car navigation device, electronic notebook, calculator, word processor, workstation, mobile phone A video phone, a POS terminal, a device provided with a touch panel, and the like are examples of the electronic device shown in FIG.
[0112]
As described above, according to the present embodiment, various electronic devices including a liquid crystal display device having a relatively simple configuration, capable of multi-gradation display, and having high reliability in gradation display. realizable.
[0113]
【The invention's effect】
According to the liquid crystal display panel driving apparatus of the present invention described above, the first period in which the data signal takes a voltage value for turning on the two-terminal nonlinear element is changed (modulated) according to the gradation level of the display data. ), It is possible to display gray scales, and there is a need for means for generating a large number of voltage levels corresponding to the number of gray scales and a means for simultaneously supplying data signals having a large number of voltage levels for each row as in the prior art. Instead, it is possible to realize a liquid crystal display panel driving device that enables multi-tone image display using a scanning signal driving circuit and a data signal driving circuit having a relatively simple configuration.
In addition, it is possible to realize a liquid crystal display panel driving device in which the gradation level can be stably changed for each selection period by using a scanning signal driving circuit and a data signal driving circuit having a relatively simple configuration.
In addition, it is possible to realize a liquid crystal display panel driving device that enables multi-tone image display using a scanning signal driving circuit and a data signal driving circuit having simpler configurations.
In addition, by using a scanning signal driving circuit and a data signal driving circuit having a relatively simple configuration, it is possible to realize a liquid crystal display panel driving device capable of gradation display using the entire range in which the transmittance of the liquid crystal changes. .
Further, when the gradation control is performed by changing the first period according to the gradation level of the display data, the change in the first period becomes equal intervals according to the gradation level. Regardless of the non-linear characteristic, control of the change (for example, pulse width modulation) in the first period in the data signal driving means can be simplified.
Further, since the range of values that can be taken by the voltage value for turning on and off the two-terminal nonlinear element in the data signal is widened, the on / off state of the two-terminal nonlinear element can be stably switched. In addition, there is a margin in the circuit design of the drive circuit.
In addition, various electronic devices such as a liquid crystal projector, a personal computer, and a pager that are excellent in economy and reliability in gradation operation and capable of multi-gradation display can be realized.
[Brief description of the drawings]
FIG. 1 is a plan view showing an example of an MIM driving element provided in an embodiment of a liquid crystal display panel according to the present invention together with a pixel electrode.
FIG. 2 is a cross-sectional view taken along the line AA of FIG.
FIG. 3 is a graph showing voltage-current characteristics of an MIM driving element.
FIG. 4 is an equivalent circuit diagram showing a circuit constituting the embodiment of the liquid crystal display panel.
FIG. 5 is a partially broken perspective view schematically showing an embodiment of a liquid crystal display panel.
FIG. 6 is a graph showing transmittance characteristics with respect to applied voltage in a liquid crystal display panel.
FIG. 7 is a waveform diagram (part 1) illustrating a scanning signal and a data signal generated by the first embodiment of the driving circuit;
FIG. 8 is a waveform diagram showing a scanning signal and a data signal generated by the first embodiment of the driving circuit (No. 2).
FIG. 9 is a waveform diagram showing scan signals and data signals generated by the first embodiment of the drive circuit (part 3);
FIG. 10 is a block diagram of a data signal drive circuit in the first embodiment of the drive circuit.
FIG. 11 is a timing chart showing how the data signal driving circuit according to the first embodiment of the driving circuit generates a data signal corresponding to a gradation level using a GCP signal.
FIG. 12 is a waveform diagram showing scanning signals and data signals generated by the second embodiment of the driving circuit.
FIG. 13 is a waveform diagram showing scanning signals and data signals generated by the third embodiment of the driving circuit.
FIG. 14 is a waveform diagram showing a scanning signal generated by a modification of the driving circuit.
FIG. 15 is a block diagram showing a schematic configuration of an embodiment of an electronic apparatus according to the invention.
FIG. 16 is a cross-sectional view illustrating a liquid crystal projector as an example of an electronic apparatus.
FIG. 17 is a front view showing a personal computer as another example of an electronic apparatus.
FIG. 18 is an exploded perspective view showing a pager as an example of an electronic apparatus.
FIG. 19 is a perspective view showing a liquid crystal display device using TCP as an example of an electronic apparatus.
FIG. 20 is a waveform diagram showing the basic principle of pulse amplitude modulation of a data signal.
FIG. 21 is a waveform diagram showing a relationship between a selection period and an on / off change in a binary data signal.
[Explanation of symbols]
10 ... Liquid crystal display panel
12 ... Scanning line
14 ... Data line
18 ... Liquid crystal layer
20 ... MIM drive element
30 ... MIM array substrate
32 ... Counter substrate
34 ... Pixel electrode
100: Scanning line driving circuit
110: Data signal driving circuit
111 ... X counter
112 ... GCP generation circuit
113 ... X driver circuit
1100 ... Liquid crystal projector
1200 ... personal computer
1300 ... Pager

Claims (10)

A pair of first and second substrates; a liquid crystal sandwiched between the first and second substrates; a plurality of pixel electrodes provided in a matrix on the side of the first substrate facing the liquid crystal; A plurality of data lines arranged in a predetermined first direction on one of the first and second substrates, and a plurality of scans arranged in a second direction intersecting the first direction on the other of the first and second substrates. And a plurality of two-terminal type non-linear elements each having a bidirectional diode characteristic interposed between the plurality of data lines or scanning lines formed on the first substrate and the plurality of pixel electrodes, respectively. A display panel driving device comprising:
Scanning signal driving means for supplying a scanning signal comprising a pulse whose voltage value continuously increases or decreases within a selection period to the scanning line;
The width of the first period in which the voltage value for turning on the two-terminal nonlinear element is changed according to the gradation level of the display data by changing the voltage value of the pulse of the scanning signal within the selection period. A data signal having a voltage value for turning off the two-terminal nonlinear element by a difference from a voltage value of a pulse of the scanning signal in a second period excluding the first period within the selection period, Data signal driving means for supplying to,
The liquid crystal display characterized in that the scanning signal driving means generates the scanning signal in which the voltage value of the pulse changes nonlinearly so that the width of the first period becomes equal intervals according to the gradation level. Panel drive device.   2. The liquid crystal display panel driving device according to claim 1, wherein the data signal driving unit generates the data signal so as to take a voltage value to be turned off in a non-selection period other than the selection period. . The scanning signal driving means generates the scanning signal so that the voltage value of the pulse increases within the selection period,
3. The liquid crystal display panel according to claim 1, wherein the data signal driving unit generates the binary data signal of the voltage value to be turned on and the voltage value to be turned off. 4. Drive device. The difference at the end of the first period when the width of the first period is the minimum corresponds to a voltage at which the change in the transmittance of the pixels of the liquid crystal display panel starts , and the width of the first period is the maximum. The scanning signal driving unit and the data signal driving unit generate the scanning signal and the data signal, respectively, so that the difference at the end of the first period corresponds to a voltage at which the transmittance is saturated. The liquid crystal display panel drive device according to claim 3. The scanning signal driving unit generates the scanning signal so that the voltage value of the pulse decreases within the selection period,
3. The liquid crystal display panel according to claim 1, wherein the data signal driving unit generates the binary data signal of the voltage value to be turned on and the voltage value to be turned off. 4. Drive device. A pair of first and second substrates; a liquid crystal sandwiched between the first and second substrates; a plurality of pixel electrodes provided in a matrix on the side of the first substrate facing the liquid crystal; A plurality of data lines arranged in one predetermined first direction on one of the first and second substrates, and a plurality of scans arranged in a second direction intersecting the first direction on the other of the first and second substrates. And a plurality of two-terminal type non-linear elements each having a bidirectional diode characteristic interposed between the plurality of data lines or scanning lines formed on the first substrate and the plurality of pixel electrodes. A display panel driving device comprising:
  Scanning signal driving means for supplying a scanning signal comprising a pulse whose voltage value continuously decreases within a selection period to the scanning line;
  The width of the first period in which the voltage value for turning on the two-terminal nonlinear element is changed according to the gradation level of the display data according to the difference from the voltage value of the pulse of the scanning signal within the selection period. A data signal that takes a voltage value for turning off the two-terminal nonlinear element in accordance with a difference from the voltage value of the pulse of the scanning signal in a second period excluding the first period within the selection period. Data signal driving means for supplying the signal to the data line
  A drive device for a liquid crystal display panel. The difference at the start of the first period when the width of the first period is the maximum corresponds to a voltage at which the change in transmittance in the pixels of the liquid crystal display panel starts , and the width of the first period is the minimum. The scanning signal driving unit and the data signal driving unit generate the scanning signal and the data signal, respectively, so that the difference at the start time of the first period corresponds to a voltage at which the transmittance is saturated. The liquid crystal display panel drive device according to claim 6 . The scanning signal driving means, the liquid crystal display panel according to any one of claims 1 to 7, characterized in that to generate the scan signals including a predetermined bias voltage in non-selection period other than the selection period Drive device.   A liquid crystal display device comprising the liquid crystal display panel driving device according to claim 1 and the liquid crystal display panel.   An electronic apparatus comprising the liquid crystal display device according to claim 9.

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