JP4386608B2 - Electro-optical device, driving method thereof, and electronic apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electro-optical device that performs gradation display control by a subfield driving method, a driving method thereof, and an electronic apparatus.
[0002]
[Prior art]
An electro-optical device, for example, a liquid crystal display device using a liquid crystal as an electro-optical material, is widely used as a display device in place of a cathode ray tube (CRT) in a display unit of various information processing devices, a liquid crystal television, and the like.
[0003]
Such a liquid crystal display device includes, for example, an element substrate provided with pixel electrodes arranged in a matrix, switching elements such as TFTs (Thin Film Transistors) connected to the pixel electrodes, and pixel electrodes. And a counter substrate on which a counter electrode is formed, and a liquid crystal as an electro-optical material filled between the two substrates.
[0004]
The display modes of the liquid crystal display device having such a configuration include normally white, which is a mode for displaying white when no voltage is applied, and normally black, which is a mode for displaying black.
[0005]
Next, an operation of displaying an image with gradation in the liquid crystal display device will be described.
[0006]
The switching element is turned on by a scanning signal supplied via the scanning line. An image signal having a voltage corresponding to the gradation is applied to the pixel electrode through the data line in a state where the scanning signal is applied to make the switching element conductive. Then, charges corresponding to the voltage of the image signal are accumulated in the pixel electrode and the counter electrode. After the charge accumulation, even if the scanning signal is removed and the switching element is made non-conductive, the charge accumulation state at each electrode is maintained by the capacitance of the liquid crystal layer, the accumulation capacity, and the like.
[0007]
In this way, when each switching element is driven and the amount of charge to be stored is controlled according to the gradation, the alignment state of the liquid crystal changes for each pixel, the light transmittance changes, and the brightness changes for each pixel. be able to. In this way, gradation display is possible.
[0008]
Considering the capacitive properties of the liquid crystal layer and the storage capacitor, it is only necessary to apply a charge to the liquid crystal layer of each pixel during a part of the period. Therefore, when driving a plurality of pixels arranged in a matrix, a scanning signal is simultaneously applied to each pixel connected to the same scanning line by each scanning line, and an image signal is applied to each pixel via the data line. The scanning lines for supplying and image signals may be switched sequentially. That is, the liquid crystal display device can perform time-division multiplex driving in which the scanning lines and the data lines are made common to a plurality of pixels.
[0009]
However, the image signal applied to the data line is a voltage corresponding to the gradation, that is, an analog signal. For this reason, an analog circuit, an operational amplifier, and the like are required for the peripheral circuit of the electro-optical device, which increases the cost of the entire device. In addition, display unevenness occurs due to the non-uniformity of these analog circuits, operational amplifiers, etc., and various wiring resistances, so that high quality display is extremely difficult. These problems become conspicuous when displaying.
[0010]
Therefore, in order to solve the above problem, a subfield driving method for digitally driving a pixel has been proposed in an electro-optical device such as a liquid crystal device. In the subfield driving method, one field is divided into a plurality of subfields on the time axis, and an on voltage or an off voltage is applied to each pixel in accordance with the gradation for each subfield.
[0011]
This subfield drive system does not change the level of the voltage applied to the liquid crystal, but changes the voltage applied to the liquid crystal according to the application time of the voltage pulse applied to the liquid crystal, thereby controlling the transmittance of the liquid crystal panel It is supposed to be. Therefore, the voltage level necessary for driving the liquid crystal is only two values of an on level and an off level.
[0012]
[Problems to be solved by the invention]
By the way, in the liquid crystal device, due to the application of the direct current component of the applied signal, for example, decomposition of the liquid crystal component, contamination due to impurities in the liquid crystal cell occurs, and a phenomenon such as burn-in of a display image appears. Therefore, in general, inversion driving is performed to invert the polarity of the driving voltage of each pixel electrode for each field in the image signal, for example.
[0013]
As described above, in the liquid crystal device, the driving voltage is applied to the pixel only during a part of the period in consideration of the capacitance. However, during a period in which the drive voltage is not applied, the voltage applied to the pixel gradually decreases due to the influence of the coupling capacitance and charge leakage.
[0014]
In the case of adopting the surface inversion driving method in which the polarity of the driving voltage of all the pixel electrodes constituting the image display area is the same and inverts at a constant cycle, charge leakage occurs during positive polarity driving and negative polarity driving. Due to the difference in the amount, the brightness of the screen changes between the positive polarity driving and the negative polarity driving, and flicker which is flickering for each field appears. In particular, in the halftone area, the influence of such potential fluctuations easily appears on the screen display. Therefore, in the liquid crystal device, inversion processing is performed in combination with inversion processing for each field, for example, line inversion that changes the polarity of the drive voltage for each line.
[0015]
However, in line inversion driving or the like, an electric field (hereinafter referred to as a lateral electric field) is generated between adjacent pixel electrodes on the same substrate in the column direction or the row direction to which voltages having different polarities are applied. This lateral electric field affects the rotation of the liquid crystal molecules in the tilt direction. That is, when line inversion is performed, a potential difference is generated between adjacent pixels, and electric lines of force are generated between adjacent pixels. In the liquid crystal device that controls the alignment state of the liquid crystal by the electric field generated between the pixel electrode and the counter electrode due to the influence of the electric lines of force, there is a problem that the image quality is deteriorated.
[0016]
The present invention has been made in view of such problems, and an electro-optical device capable of improving the image quality by enabling the influence of leakage or the like to be avoided even when only surface inversion driving is employed, and driving thereof It is an object to provide a method and an electronic device.
[0017]
[Means for Solving the Problems]
An electro-optical device according to the present invention is arranged in a matrix with an electro-optical material interposed therebetween, and the electro-optical material is provided for a display unit including each pixel whose light transmittance is variable by applying a voltage. By supplying an on-voltage that is equal to or higher than the saturation voltage or an off-voltage that is equal to or lower than the threshold voltage, gradation expression is performed according to the state of light transmission and non-transmission and the time ratio of the electro-optic material in unit time. In an electro-optical device that drives the pixel using each subfield divided into a plurality of fields on a time axis as a control unit, the subfield to which the on voltage is applied and the off voltage are Latch means for latching binary data designating a subfield to be applied based on display data; For each inversion driving period that is a plurality of subfield periods or field periods, surface inversion driving is performed by applying a positive voltage having a higher potential than a predetermined reference potential or a negative voltage having a lower potential to each pixel. In the inversion driving cycle for the pixel, the difference between the on-voltage and the saturation voltage of the electro-optic material is prevented so that the voltage applied to the pixel does not become lower than the saturation voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. Is set to be equal to or greater than the potential fluctuation amount generated in the voltage applied to the pixel in the inversion driving period for the pixel, and the voltage applied to the pixel is greater than or equal to the threshold voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. The latch means latches the difference between the off-voltage and the threshold voltage of the electro-optic material to be equal to or more than the amount of potential fluctuation generated in the voltage applied to the pixel in the inversion driving cycle for the pixel. Pixel driving means for converting binary data into the on-voltage or off-voltage and applying it to the pixel, the pixel driving means comprising: The serial off voltage, the driving polarity opposite the voltage of the inverting driving period, the absolute value and sets the voltage smaller than the absolute value of the threshold voltage.
[0018]
According to such a configuration, the electro-optical material constituting each pixel has a variable light transmittance by applying a voltage. Each subfield obtained by dividing the field into a plurality on the time axis is a control unit, and each pixel is driven in the subfield by applying an ON voltage or an OFF voltage to the electro-optical material. The latch means latches binary data specifying an on voltage or an off voltage based on display data. The pixel driving means sets the difference between the on-voltage and the saturation voltage of the electro-optic material to be equal to or more than the amount of potential fluctuation generated in the voltage applied to the pixel in the inversion driving cycle for the pixel, and the off-voltage and the threshold voltage of the electro-optic material. And the latched binary data is converted to an on voltage or an off voltage and applied to the pixel. The potential of the voltage applied to the pixel fluctuates within the inversion driving cycle. Even in this case, since the difference between the on-voltage and the saturation voltage and the difference between the off-voltage and the threshold voltage are equal to or greater than the potential fluctuation amount, the saturation state or non-transmission state of the electro-optical material is not changed by the potential fluctuation. Absent. Thereby, it is possible to prevent the display from being changed within the screen and between the screens due to the potential fluctuation, and it is possible to prevent the occurrence of flicker and the unevenness of the screen display.
[0019]
Further, the pixel driving means sets the ON voltage higher than the saturation voltage by the potential fluctuation amount or more than the saturation voltage and sets the OFF voltage to the potential higher than the threshold voltage during the positive driving period of the inversion driving cycle. The ON voltage is set lower than the saturation voltage and the OFF voltage is set lower than the threshold voltage during the negative driving period of the inversion driving cycle. It is characterized by being set higher than the amount.
[0020]
According to such a configuration, in the positive drive period of the inversion drive cycle, the on-voltage does not become lower than the saturation voltage due to potential fluctuation, and the off-voltage does not become higher than the threshold voltage. Further, in the negative drive period of the inversion drive cycle, the on-voltage does not exceed the saturation voltage due to potential fluctuations, and the off-voltage does not fall below the threshold voltage. Accordingly, the saturation state or the non-transmission state of the electro-optical material is prevented from changing due to the potential fluctuation, and flickering and screen display unevenness are prevented.
[0021]
The pixel driving unit may set the off voltage to a voltage having a polarity opposite to a driving polarity in an inversion driving cycle and an absolute value smaller than an absolute value of the threshold voltage.
[0022]
According to such a configuration, even when the difference between the absolute value of the threshold voltage and the reference potential is smaller than the amount of potential fluctuation generated in the voltage applied to the pixel in the inversion driving cycle for the pixel, the off voltage and the threshold voltage The difference can be set to be greater than or equal to the potential fluctuation amount.
[0023]
The inversion driving period is a subfield period.
[0024]
Such a configuration is applicable to subfield inversion driving.
[0025]
Further, the inversion driving cycle is a field cycle.
[0026]
Such a configuration is applicable to field inversion driving.
[0027]
The inversion driving period may be a plurality of subfield periods or a plurality of field periods.
[0028]
Such a configuration can be applied to inversion driving of a plurality of subfield periods or a plurality of field periods.
[0029]
Further, the pixel driving means sets the ON voltage to a value 1.5 times the saturation voltage.
[0030]
According to such a configuration, even when the amount of potential fluctuation in the inversion driving cycle is relatively large, the on-voltage can be reliably maintained at the saturation voltage or higher at the end of the inversion driving cycle.
[0031]
In the driving method of the electro-optical device according to the invention, the electro-optical material is sandwiched and arranged in a matrix, and the display unit including each pixel whose light transmittance is variable by applying a voltage is described above. By supplying an on-voltage that is greater than or equal to the saturation voltage of the electro-optic material or an off-voltage that is less than or equal to the threshold voltage, the gray level is varied according to the state of light transmission and non-transmission and the time ratio of the electro-optic material in unit time. In a driving method of an electro-optical device for driving the pixel using each subfield obtained by dividing the field into a plurality of subfields on a time axis as a control unit. A latch procedure for latching binary data designating a field and a subfield to which the off voltage is applied based on display data; For each inversion driving period that is a plurality of subfield periods or field periods, surface inversion driving is performed by applying a positive voltage having a higher potential than a predetermined reference potential or a negative voltage having a lower potential to each pixel. In the inversion driving cycle for the pixel, the difference between the on-voltage and the saturation voltage is set so that the voltage applied to the pixel does not become lower than the saturation voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. In addition, the voltage applied to the pixel is set to be not less than the threshold voltage of the electro-optic material due to the influence of the coupling capacitance or charge leakage. In addition, the difference between the off-voltage and the threshold voltage is set to be equal to or greater than the amount of potential fluctuation generated in the voltage applied to the pixel in the inversion driving cycle for the pixel, and the binary data latched in the latching procedure is set to the on-state. A pixel driving procedure for converting the voltage into an off-voltage or applying it to the pixel, and in the pixel driving procedure, Pressure and the drive polarity opposite the voltage of the inverting driving period, the absolute value and sets the voltage smaller than the absolute value of the threshold voltage.
[0032]
According to such a configuration, the electro-optical material constituting each pixel has a variable light transmittance by applying a voltage. In sub-field driving, each pixel is driven by applying an on-voltage or an off-voltage to the electro-optic material using each sub-field divided into a plurality of fields on the time axis as a control unit. First, binary data designating an on voltage or an off voltage based on display data is latched. Next, the latched binary data is converted into an on voltage or an off voltage and applied to the pixel. In this case, the difference between the on voltage and the saturation voltage is set to be greater than or equal to the potential fluctuation amount generated in the voltage applied to the pixel in the inversion driving cycle for the pixel, and the difference between the off voltage and the threshold voltage is also greater than or equal to the potential fluctuation amount. Set to As a result, the saturation state or non-transmission state of the electro-optical material does not change at the end of the inversion driving cycle due to the potential fluctuation, and the occurrence of flicker and the occurrence of screen display unevenness are prevented.
[0033]
An electronic apparatus according to the present invention includes the electro-optical device.
[0034]
According to such a configuration, the occurrence of flicker and the occurrence of screen display unevenness are prevented, and display with high image quality is possible.
[0035]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram showing an electro-optical device according to a first embodiment of the invention.
[0036]
The electro-optical device according to the present embodiment is, for example, a liquid crystal device using liquid crystal as an electro-optical material. As described later, an element substrate and a counter substrate are attached to each other with a predetermined gap therebetween, and the electric substrate is electrically connected to the gap. The liquid crystal which is an optical material is sandwiched. Here, the display mode of the electro-optical device is normally black, and it is assumed that white display is performed when a voltage is applied to the pixel (on state) and black display is performed when no voltage is applied (off state). To do.
[0037]
In this embodiment, as a liquid crystal driving method, one field is divided into a plurality of subfields on the time axis as a control unit, and subfield driving is used to control liquid crystal driving for each subfield period. To do.
[0038]
When intermediate brightness is obtained by analog driving, the liquid crystal is driven at a voltage equal to or lower than a driving voltage that saturates the transmittance of the liquid crystal (hereinafter referred to as a liquid crystal saturation voltage). Therefore, the transmittance of the liquid crystal is approximately proportional to the drive voltage, and a screen with brightness proportional to the drive voltage is obtained.
[0039]
On the other hand, in the subfield driving, a driving voltage (hereinafter referred to as an “on voltage”) higher than the liquid crystal saturation voltage is applied to the liquid crystal to saturate the transmittance of the liquid crystal. A screen having a brightness substantially proportional to the ratio of the time during which the on-voltage is applied to the time during which the off-voltage is applied, that is, the time during which the drive voltage is applied per relatively short unit time (for example, one field period) is obtained. It is like that.
[0040]
That is, a pulse signal (pixel writing data) having a pulse width corresponding to one subfield period Ts is used as a driving signal for driving the liquid crystal. The pulse signal is a binary signal of 1 or 0. For example, assuming that one field is equally divided into 255 subfields and the brightness to be displayed is N brightnesses for 256 gradations, the pulse signal is timed for N subfields, that is, Control is performed so that only (Ts × N) is output, and the voltage is not applied in the remaining (255-N) subfield period of one field period. Thereby, N brightnesses for 256 gradations can be obtained.
[0041]
In this case, a drive pattern (hereinafter referred to as subfield drive) of a subfield that applies an on voltage to the liquid crystal of each pixel and a subfield that applies an off voltage (a voltage equal to or lower than a threshold voltage for making the liquid crystal non-transmissive). There are various possible patterns). For example, a pattern in which the ON voltage is continuously applied for the number of subfield periods corresponding to the brightness from the start of the field (hereinafter referred to as a response-oriented pattern) can be considered.
[0042]
The transmittance of the liquid crystal is changed by applying a driving voltage to transition its alignment state. In this case, the response speed of the liquid crystal between the non-transmissive state and the state where the light transmittance is saturated has a characteristic that it becomes faster according to the magnitude of the electric field applied to the liquid crystal layer at a constant temperature.
[0043]
Therefore, when applying an electric field to the liquid crystal layer to make a transition from a non-transmissive state to a state where the light transmittance is saturated, a voltage as high as possible is applied at an early timing, and conversely, the light transmittance is saturated. In the case of transition from the non-transmission state to the non-transmission state, by removing the electric field from the liquid crystal layer at the earliest possible timing, the response speed can be increased and the visibility of the moving image can be improved.
[0044]
That is, an electric field is applied to the liquid crystal layer as much as possible at the end of the field by adopting a response-oriented pattern in which an on-voltage is applied only to the first half of the field and no voltage is applied to the second half of the field. Thus, high-speed response can be obtained.
[0045]
Incidentally, subfield driving is also employed in plasma displays and the like. In a plasma display or the like, a writing time (scanning time) to a pixel is required for each subfield period, and if the number of subfields in one field is increased by narrowing the subfield period, within one field period The number of times of writing to the pixels increases, and this writing shortens the light emission time and darkens the screen. Therefore, in a plasma display or the like, weighting subfield driving is performed in which the length (time width) of a subfield period in one field is changed and each subfield is weighted.
[0046]
On the other hand, the liquid crystal device can prevent the light emission time from being shortened even if the number of subfields in one field increases. Further, the greater the number of subfields in one field, the greater the number of gradations that can be expressed. Therefore, in the liquid crystal device, it is preferable to increase the number of subfields in one field in consideration of gradation expression. However, the number of subfields in one field is limited due to device restrictions on speeding up.
[0047]
Therefore, the saturation response time of the liquid crystal (the time from when the on-voltage is applied until the transmittance of 100% is obtained) is, for example, about 2 to 5 msec for projector applications, and is a subfield period time that can be realized within the device constraints. A method of increasing the number of gradations that can be expressed without increasing the number of subfields in one field by utilizing the longer than the width is employed.
[0048]
Next, control of multi-gradation display in this embodiment will be described with reference to FIG. FIG. 3 shows changes in the liquid crystal optical response (transmittance) in each subfield period within one field period, with time on the horizontal axis and liquid crystal transmittance on the vertical axis. The shaded portion in FIG. 3 indicates a subfield period in which an on voltage is applied to the liquid crystal of each pixel, and the plain portion indicates a subfield period in which an off voltage is applied.
[0049]
When an electro-optical material having a fast response characteristic, such as a plasma display, is used, as described above, a sub-field period (hereinafter referred to as a sub-field to be turned on) in which an on-voltage (driving voltage for light emission) is applied to the electro-optical material. The brightness of the pixel is determined by a time ratio between a field period (also referred to as a field period) and a subfield period (hereinafter also referred to as a subfield period during which the light is turned off) to which an off voltage (driving voltage for non-light emission) is applied. On the other hand, when the saturation response time is longer than the time width of the subfield period as in the liquid crystal, the brightness of the pixel is actually proportional to the integral value of the transmittance.
[0050]
FIG. 3 shows an example in which one field is divided into six subfields Sf1 to Sf6 on the time axis. That is, FIG. 3 shows an example in which one field period is equally divided into six and the pixel is driven in the subfield every subfield period which is each divided period.
[0051]
For each pixel, each pixel is turned on (saturated transmittance) or off (transmitted) for each subfield period Sf1 to Sf6 based on brightness data to be displayed (hereinafter referred to as gradation data). The gradation display is performed by applying a voltage for setting the ratio to 0.
[0052]
The applied voltage (drive voltage) to the pixel electrode saturates instantaneously, whereas the response of the pixel transmittance is slow, and the liquid crystal transmittance saturates after a predetermined delay time, as shown in FIG. FIG. 3 shows an example using a liquid crystal material that takes about 3 to 4 subfield periods until the liquid crystal is optically saturated when an on-voltage is applied to the liquid crystal. Also, a liquid crystal material longer than one subfield period is used for the non-transmission response time until the transmittance shifts from the saturation state to the non-transmission state when the off voltage is applied.
[0053]
That is, in the example of FIG. 3, in the first subfield period after the on-voltage is applied, the liquid crystal changes to a transmittance of 4/10 of the saturated transmittance, and by the next subfield period, that is, after the on-voltage is applied. The transmittance changes to 7/10 in the 2 subfield period, changes to 8/10 in the 3 subfield period after the ON voltage is applied, and 10/10 transmits in the 4 subfield period after the ON voltage is applied. An example of changing the rate is shown.
[0054]
In the example of FIG. 3, the transmittance of the liquid crystal decreases by 3/10 in the first subfield period after the off voltage is applied, and the transmittance decreases by 5/10 in the two subfield periods after the off voltage is applied. In this example, the transmittance decreases by 7/10 in the three subfield periods after the off voltage is applied, and the transmittance decreases by 9/10 in the four subfield periods after the off voltage is applied.
[0055]
FIG. 3A shows an example in which an on-voltage is applied during the first three subfield periods of the field period and an off-voltage is applied during the latter three subfield periods. The transmittance of the liquid crystal increases to 4/10 of the saturated transmittance in the first subfield period, and increases to 7/10 of the saturated transmittance in the second subfield period. It rises to 8/10 of the saturated transmittance over time. Further, the transmittance decreases to 5/10 of the saturated transmittance in the fourth subfield period, decreases to 3/10 in the fifth subfield period, and decreases in the sixth subfield period. The transmittance is reduced to 1/10.
[0056]
As described above, when the subfield driving cycle (one field period in the example of FIG. 3) is sufficiently short, the brightness changes in proportion to the integral value of the transmittance. Assuming that complete white display can be obtained when display is performed at 100% transmittance in all subfield periods, the brightness in the field period of FIG. 3A is the full white display {(4 + 7 + 8 + 5 + 3 + 1). / 10} × 1/6 = 28/60 brightness.
[0057]
Similarly, in the example of FIG. 3B, the brightness is {(4 + 3 + 1) / 10} × 1/6 = 8/60 for complete white display. In the example of FIG. 3C, the brightness is {(4 + 3 + 1 + 4 + 3 + 1) / 10} × 1/6 = 16/60 for complete white display. Further, in the example of FIG. 3D, the brightness is {(4 + 7 + 4 + 3 + 2 + 1) / 10} × 1/6 = 21/60 for complete white display.
[0058]
When the subfield period in which the on-voltage is applied is simply continued, only 6 + 1 = 7 gradation display can be obtained by the subfield period divided into six. On the other hand, in the example of FIG. 3, a subfield drive pattern (hereinafter referred to as a tone reproducibility emphasis pattern) in which the position of the subfield period to which the on voltage is applied and the position of the subfield period to which the off voltage is applied is appropriately set. By adopting, it is possible to display with a number of gradations significantly higher than 7 gradations.
[0059]
For example, when one field is divided into 16 subfields on the time axis, if the subfield period in which the ON voltage is simply applied is continued, only 17 gradations can be obtained by the 16 subfields. In consideration of the arrangement of the subfields to be turned off and the subfields to be turned off, gradation expression of 160 gradations or more is possible. Similarly, when one field is divided into 32 subfields on the time axis, gradation representation of 256 gradations or more is possible.
[0060]
By the way, as described above, in the subfield driving, an on voltage is applied to the liquid crystal to saturate the transmittance of the liquid crystal. In subfield driving, whether the on-voltage is turned on or off, even when an on-voltage higher than the saturation voltage is applied, and conversely, an off-voltage less than the threshold voltage is applied. Only determined by. That is, a voltage higher than the saturation voltage or a voltage lower than the threshold voltage can be applied to the liquid crystal as the on voltage and the off voltage without affecting the transmittance.
[0061]
By utilizing this characteristic, in the present embodiment, an on-voltage that is sufficiently higher than the saturation voltage (having a large absolute value) is applied to the liquid crystal in consideration of the amount of leakage that occurs during the subfield period, and the amount of leakage In consideration of the above, an off voltage sufficiently lower than the threshold voltage (small absolute value) is applied to the liquid crystal. This prevents the transmittance from changing due to leakage or the like even when polarity inversion driving is performed. The inversion period at this time may be a subfield or a field.
[0062]
In FIG. 1, the electro-optical device according to the present embodiment includes a display area 101a using a liquid crystal that is an electro-optical material, a scan driver 401 and a data driver 500 that drive each pixel in the display area 101a, and scanning of these. The driving circuit 301 supplies various signals to the driver 401 and the data driver 500.
[0063]
In the electro-optical device according to the present embodiment, a transparent substrate such as a glass substrate is used as an element substrate, and a peripheral driving circuit and the like are formed on the element substrate together with transistors for driving pixels. In the display area 101a on the element base slope, a plurality of scanning lines 112 are formed extending in the X (row) direction of FIG. 1, and a plurality of data lines 114 are formed in the Y (column) direction. It is formed extending along. The pixels 110 are provided corresponding to the intersections of the scanning lines 112 and the data lines 114 and are arranged in a matrix.
[0064]
For convenience of explanation, in this embodiment, the total number of scanning lines 112 is m and the total number of data lines 114 is n (m and n are integers of 2 or more), respectively, and a matrix of m rows and xn columns. Although described as a type display device, the present invention is not limited to this.
[0065]
FIG. 4 is an explanatory diagram showing a specific configuration of the pixel in FIG.
[0066]
Each pixel 110 is provided with a transistor (pSiTFT) 116 as a switching means. The transistor 116 has a gate connected to the scanning line 112, a source connected to the data line 114, and a drain connected to the pixel electrode 118. A liquid crystal layer is formed between the pixel electrode 118 and the counter electrode 108 by sandwiching a liquid crystal 105 as an electro-optical material. As will be described later, the counter electrode 108 is actually a transparent electrode formed on the entire surface of the counter substrate so as to face the pixel electrode 118.
[0067]
A counter electrode voltage VLCCOM is applied to the counter electrode 108. In addition, a storage capacitor 119 is formed between the pixel electrode 118 and the counter electrode 108, and charges are stored together with electrodes sandwiching the liquid crystal layer. In the example of FIG. 4, the storage capacitor 119 is formed between the pixel electrode 118 and the counter electrode 108. However, the storage capacitor 119 may be formed between the pixel electrode 118 and the ground potential GND or between the pixel electrode 118 and the gate line. . Further, a wiring having the same potential as the counter electrode voltage VLCCOM may be arranged on the element substrate side and formed between them.
[0068]
Each scanning line 112 is supplied with scanning signals G1, G2,... Gm from a scanning driver 401 described later. Each of the scanning signals simultaneously turns on all the transistors 116 constituting the pixels of each line, whereby an image signal supplied from the data driver 500 described later to each data line 114 is written to the pixel electrode 118. The alignment state of the molecular assembly of the liquid crystal 105 changes in accordance with the potential difference between the pixel electrode 118 to which the image signal is written and the counter electrode 108, and light modulation is performed, so that gradation display is possible.
[0069]
As described above, in this embodiment, one field is divided into a plurality of subfields on the time axis, and writing of each pixel 110 is controlled for each subfield period.
[0070]
Next, the configuration of the drive system that drives the display area will be described. FIG. 2 is a block diagram showing a specific configuration of the drive circuit 301 in FIG.
[0071]
In FIG. 2, the vertical synchronization signal Vs, the horizontal synchronization signal Hs, and the dot clock DCLK supplied from the outside are input to the subfield timing generator 10. The subfield timing generator 10 generates a timing signal used in the subfield system based on the input horizontal synchronization signal Hs, vertical synchronization signal Vs, and dot clock DCLK.
[0072]
That is, the subfield timing generator 10 generates a data transfer clock CLX, a data enable signal ENBX, and a polarity inversion signal FR, which are display driving signals, and outputs them to the data driver 500. Further, the subfield timing generator 10 generates a scan start pulse DY and a scan-side transfer clock CLY and outputs them to the scan driver 401. The subfield timing generator 10 generates a data transfer start pulse DS and a subfield identification signal SF used inside the controller and outputs them to the data encoder 30.
[0073]
The scan start pulse DY is a pulse signal output at the start point of each subfield. When the scan start pulse DY is input to the scan driver 401, the scan driver 401 sequentially outputs gate pulses (G1 to Gm). To do.
[0074]
As described above, one field is divided into a plurality of subfields Sf1 to Sfs on the time axis, and a binary voltage is applied to the liquid crystal layer for each subfield period according to the gradation data. The start pulse DY is a signal indicating switching of each subfield, and writing scanning to the display area is performed for each output.
[0075]
The scanning side transfer clock CLY is a signal that defines the scanning speed (Y side), and the gate pulses (G1 to Gm) are sent for each scanning line in synchronization with the transfer clock. The data enable signal ENBX determines the timing at which data stored in an X bit shift register 510 (to be described later) in the data driver 500 is output in parallel for the number of horizontal pixels. The data transfer clock CLX is a clock signal for transferring data to the data driver 500. The data transfer start pulse DS defines the timing at which data transfer from the data encoder 30 to the data driver 500 is started, and is sent from the subfield timing generator 10 to the data encoder 30. The subfield identification signal SF is for informing the data encoder 30 of what number the pulse (subfield) is.
[0076]
In the present embodiment, the subfield timing generator 10 generates a signal whose polarity is inverted every subfield as the polarity inversion signal FR when performing the subfield inversion driving which is the surface inversion driving method. Further, when performing field inversion driving which is a surface inversion driving method, the subfield timing generator 10 generates a signal whose polarity is inverted every field as the polarity inversion signal FR.
[0077]
The driving voltage generation circuit 40 generates a voltage for obtaining a scanning signal and supplies it to the scanning driver 401, generates voltages Von, -Von, Voff, and -Voff for obtaining a data line driving signal and supplies them to the data driver 500. The counter electrode voltage VLCCOM is generated and applied to the counter electrode 108.
[0078]
7 and 8 are for explaining the voltage generated by the drive voltage generation circuit 40 in FIG.
[0079]
FIG. 7 is a graph showing the drive voltage-transmittance characteristics of a normally black display liquid crystal with the voltage V on the horizontal axis and the transmittance T on the vertical axis. The voltages Vth and Vsat in FIG. 7 indicate the threshold voltage or saturation voltage of the liquid crystal, respectively. As shown in FIG. 7, at the time of positive polarity driving, the liquid crystal is saturated to the maximum value at a voltage equal to or higher than the saturation voltage Vsat, and conversely, the transmittance is minimum at a voltage equal to or lower than the threshold voltage Vth. Note that, during negative polarity driving, the liquid crystal is saturated at the maximum value at a voltage equal to or lower than the negative saturation voltage −Vsat, and the transmittance is at the minimum value at a voltage equal to or higher than the negative threshold voltage −Vth.
[0080]
FIG. 8 is an explanatory diagram showing the relationship between the saturation voltage and threshold voltage and the voltages Von, −Von, Voff, and −Voff generated by the drive voltage generation circuit 40. FIG. 8 shows the polarity and level of voltage with respect to COM in the vertical direction. Here, the voltage COM is a reference voltage for driving the liquid crystal, and is substantially equal to the voltage VLCCOM of the counter electrode. In this example, polarity inversion is performed in a field cycle, and writing with the same polarity continues for the number of subfields.
[0081]
The voltage + Von is a data line drive signal (ON voltage) that is output as a positive high level signal with reference to the voltage COM to the liquid crystal layer when the AC drive signal FR is at a high level (hereinafter referred to as H level). The voltage −Von is a data line drive signal (ON voltage) output as a negative high level signal with reference to the voltage COM when the alternating drive signal FR is at a low level (hereinafter referred to as L level). It is.
[0082]
The voltage + Voff is a data line drive signal (off voltage) output as a negative low level signal with reference to the voltage COM when the alternating drive signal FR is at the H level, and the voltage −Voff is This is a data line drive signal (off voltage) that is output as a positive low level signal to the liquid crystal layer with reference to the voltage COM when the AC drive signal FR is at the L level.
[0083]
That is, in the present embodiment, the voltage Von applied to the liquid crystal as the on-voltage during the liquid crystal inversion driving positive polarity driving is set to a voltage sufficiently higher than the saturation voltage + Vsat, and is applied to the liquid crystal as the off-voltage during positive polarity driving. The applied voltage + Voff is set to a negative voltage sufficiently lower than the threshold voltage + Vth. In the negative polarity driving of the liquid crystal inversion driving, the voltage −Von applied to the liquid crystal as the on voltage is set to a voltage sufficiently lower than the saturation voltage −Vsat, and the voltage −Voff applied to the liquid crystal as the off voltage is a threshold value. The positive voltage is set sufficiently higher than the voltage −Vth. Here, + Vth and -Vth are set so as to be smaller in absolute value than the threshold voltage of the liquid crystal in opposite polarities.
[0084]
When the field inversion driving is performed, the drive voltage generation circuit 40 determines the difference between the on voltage + Von and the saturation voltage + Vsat, the difference between the on voltage −Von and the saturation voltage −Vsat, and the off voltage −Voff and the threshold voltage + Vth. The difference and the difference between the off voltage −Voff and the threshold voltage −Vth are set to be larger than the potential fluctuation amount (leakage amount or the like) in the subfield period in the subfield drive. Similarly, when subfield inversion driving is performed, the difference is set to be larger than the potential fluctuation amount in the subfield period. In the case of subfield inversion driving, since the driving polarity is inverted for each subfield, it is not uniquely determined to which polarity side the potential of the pixel fluctuates, particularly for a pixel driven with an off voltage. Therefore, when performing subfield inversion driving, both + Voff and -Voff are set to voltages close to the voltage COM.
[0085]
Hereinafter, this embodiment will be described in the case of field inversion driving. In this case, for example, the drive voltage generation circuit 40 sets the absolute value of the on voltage to 1.5 times or more the absolute value of the saturation voltage, and the off voltage is a voltage having a polarity opposite to the drive polarity, and A voltage whose absolute value is smaller than the absolute value of the threshold voltage is set.
[0086]
In FIG. 2, input display data is supplied to the memory controller 20. The write address generator 11 specifies the position on the screen of the data being sent at that time based on the horizontal synchronization signal Hs, the vertical synchronization signal Vs, and the dot clock DCLK input from the outside, and based on the specified result. A memory address for storing display data in the memories 23 and 24 is generated and output to the memory controller 20.
[0087]
The read address generator 12 determines the position on the screen to be displayed at that time from the subfield system timing signal generated by the subfield timing generator 10, and based on the determined result, the same rule as at the time of writing Accordingly, a memory address for reading data from the memories 23 and 24 is generated and output to the memory controller 20. The read address generator 12 outputs the position data of each pixel obtained here on the screen to the data encoder 30.
[0088]
The memory controller 20 performs control for writing the input display data into the memories 23 and 24 and reading the written data from the memories 23 and 24. That is, the memory controller 20 writes externally input data to the memories 23 and 24 with respect to the address generated by the write address generator 11 in synchronization with the timing signal DCLK. Reading is performed in synchronization with the timing signal CLX generated by the subfield timing generator 10 from the address generated by the reading address generator 12. The memory controller 20 outputs the read data to the data encoder 30.
[0089]
In subfield driving, writing to a pixel is performed for each subfield. Therefore, it is necessary to store display data in the field memory and generate binary data for determining on / off of the subfield based on the display data read from the field memory for each subfield.
[0090]
For this reason, memories 23 and 24 are provided. One of the memories 23 and 24 is used for writing input data, and the other is used for reading. The roles of these memories 23 and 24 are switched by the memory controller 20 in order for each field.
[0091]
The data encoder 30 stores a code based on the data sent from the memory controller 20, the subfield identification signal SF sent from the subfield timing generator 10, and the pixel position data sent from the read address generator 12. An address for reading necessary data from the ROM 31 is generated, the data is read from the code storage ROM 31 using the address, and output to the data driver 500 in synchronization with the data transfer start pulse DS.
[0092]
The code storage ROM 31 is a binary of H level or L level for turning on or off a pixel for each subfield period with respect to brightness data (gradation data) to be displayed for each pixel. A set of signals Dd (codes specifying whether to turn on or off each subfield in one field) is stored. When the code storage ROM 31 receives data (gradation data) to be written in each pixel and a subfield to be written as addresses, 1-bit data (binary signal (data) Dd) corresponding to the subfield is input. Is configured to output.
[0093]
In FIG. 1, a scan driver 401 transfers a scan start pulse DY supplied at the start point of a subfield according to a scan-side transfer clock CLY, and scans each line 112 as scan signals G1, G2, G3,. Supply sequentially and exclusively.
[0094]
The data driver 500 sequentially latches n pieces of binary data corresponding to the number of data lines in a certain horizontal scanning period, and then sends the n pieces of latched binary data to the corresponding data lines 114 as data signals d1, These are supplied all at once as d2, d3,.
[0095]
FIG. 5 is a block diagram showing a specific configuration of the data driver 500 in FIG.
[0096]
The data driver 500 includes an X-bit shift register 510, a first latch circuit 520 for horizontal pixels, a second latch circuit 530, and a booster circuit 540 for horizontal pixels.
[0097]
The X-bit shift register 510 transfers the data enable signal ENBX supplied at the start timing of the horizontal scanning period according to the clock signal CLX, and sequentially excludes the first latch circuit 520 as the latch signals S1, S2, S3,. To supply. The first latch circuit 520 sequentially latches binary data at the falling edges of the latch signals S1, S2, S3,. The second latch circuit 530 latches each of the binary data latched by the first latch circuit 520 at the falling edge of the data enable signal ENBX, and each of the data lines 114 via the booster circuit 540. Are supplied as data signals d1, d2, d3,.
[0098]
The booster circuit 540 has a polarity inversion function and a boost function. The booster circuit 540 boosts the binary data input based on the polarity inversion signal FR to obtain data signals d1, d2, d3,. In the present embodiment, the booster circuit 540 receives voltages Von, −Von, Voff, and −Voff from the drive voltage generation circuit 40 in the drive circuit 301, and converts binary data into these voltage values.
[0099]
FIG. 6 is an explanatory diagram for explaining the operation of the booster circuit 540. For example, in the case where the polarity inversion signal FR is at the H level, when binary data for turning on a certain pixel is input to the booster circuit 540, a positive ON voltage is output. When the polarity inversion signal FR is at the L level and the binary data for turning on a certain pixel is manually input, a negative on voltage is output.
[0100]
In the present embodiment, the booster circuit 540 uses the output of the drive voltage generation circuit 40 to output + Von as a positive on-voltage and −Von as a negative on-voltage.
[0101]
Further, the booster circuit 540 uses the output of the drive voltage generation circuit 40 to output the off voltage + Voff with the H level polarity inversion signal FR when binary data for turning the pixel off is input. The OFF voltage -Voff is output by the L level polarity inversion signal FR.
[0102]
As described above, in the data driver 500, after the first latch circuit 520 latches the binary signal dot-sequentially in a certain horizontal scanning period, the second latch circuit in the next horizontal scanning period. 530 is configured to supply the data lines 114 simultaneously as data signals d1, d2, d3,..., Dn, so that the data encoder 30 is compared with the operations in the scan driver 401 and the data driver 500. The binary signal Dd is output at a timing preceding one horizontal scanning period.
[0103]
Next, the operation of the embodiment configured as described above will be described with reference to FIGS. FIG. 9 is a waveform diagram showing drive voltages applied to the pixels in the field inversion drive, and FIG. 10 is a timing chart for explaining the operation of the electro-optical device in the present embodiment.
[0104]
First, binary data applied to each pixel in each subfield will be described.
[0105]
Display data is input to the memory controller 20 of the drive circuit 301. The memory controller 20 sequentially applies the input display data to the memories 23 and 24, and stores the display data for two fields in each of the memories 23 and 24. That is, the memory controller 20 reads the display data of the previous field from one of the memories 23 and 24 and outputs it to the data encoder 30 while writing the current display data to the remaining one memory.
[0106]
The data encoder 30 is supplied with display data from the memory controller 20, and based on the display data, designates the address of the code storage ROM 31 and reads a code corresponding to the display data. Then, the data encoder 30 outputs binary data based on the code read at each subfield timing to the data driver 500 based on the SF signal from the subfield timing generator 10.
[0107]
Next, sub-field driving of pixels will be described.
[0108]
Now, it is assumed that the liquid crystal pixel is driven by surface inversion, and the pixel is driven by inverting the polarity for each field. In this case, as shown in FIG. 10, the AC signal FR is a signal whose level is inverted every field period. The start pulse DY is generated at the start of each of the subfields Sf1 to Sfs.
[0109]
When the start pulse DY is supplied, the scanning signals G1, G2, G3,..., Gm are sequentially output exclusively in the period (t) by the transfer according to the clock signal CLY in the scanning driver 401. In the example of FIG. 10, one field is divided into s subfields having the same time width on the time axis.
[0110]
The scanning signals G1, G2, G3,..., Gm each have a pulse width corresponding to a half cycle of the scanning side transfer clock CLY, and the scanning signal G1 corresponding to the first scanning line 112 counted from the top is After the start pulse DY is supplied, the clock signal CLY rises for the first time and is output with a delay of at least a half cycle of the clock signal CLY. Therefore, one clock (G0) of the data enable signal ENBX is supplied to the data driver 500 from when the start pulse DY is supplied to when the scanning signal G1 is output.
[0111]
When the first clock (G0) of the data enable signal ENBX is supplied to the data driver 500, the latch signals S1, S2, S3,..., Sn are transferred to the horizontal scanning period (1H) by the transfer according to the data transfer clock CLX. Are sequentially output exclusively. Note that each of the latch signals S1, S2, S3,..., Sn has a pulse width corresponding to a half cycle of the data transfer clock CLX.
[0112]
As described above, the data driver 500 is also supplied with binary data from the data encoder 30. The first latch circuit 520 in FIG. 5 supplies the pixel 110 corresponding to the intersection of the first scanning line 112 counted from the top and the first data line 114 counted from the left at the falling edge of the latch signal S1. Next, at the falling edge of the latch signal S2, the pixel 110 corresponding to the intersection of the first scanning line 112 counted from the top and the second data line 114 counted from the left is latched. Thereafter, similarly, the binary data to the pixel 110 corresponding to the intersection of the first scanning line 112 counted from the top and the nth data line 114 counted from the left are sequentially sequentially thereafter. Latch.
[0113]
Thereby, first, binary data for one row corresponding to the intersection with the first scanning line 112 from the top in FIG. 1 is latched dot-sequentially by the first latch circuit 520. The data encoder 30 generates and outputs binary data corresponding to each subfield sequentially from the display data of each pixel in accordance with the latch timing of the first latch circuit 520.
[0114]
Next, when the clock signal CLY falls and the scanning signal G1 is output, the pixel corresponding to the intersection with the scanning line 112 is selected as a result of selecting the first scanning line 112 counted from the top in FIG. 110 transistors 116 are all turned on.
[0115]
On the other hand, the data enable signal ENBX (G1) is output again at the falling timing of the clock signal CLY. At the falling timing of the signal ENBX, the second latch circuit 530 receives the binary data latched dot-sequentially by the first latch circuit 520 through the booster circuit 540 for each corresponding data line 114. The signals d1, d2, d3,..., Dn are supplied all at once.
[0116]
Now, it is assumed that the AC signal FR is in the H level. In this case, a positive drive voltage is applied to each liquid crystal pixel. That is, when the binary data for turning on the subfield is given, the booster circuit 540 outputs the binary data as the on voltage + Von. Further, when the binary data for turning off the subfield is given, the booster circuit 540 outputs the binary data as a negative off voltage + Voff.
[0117]
Further, when the AC signal FR is at the L level, when the binary data for turning on the subfield is given, the booster circuit 540 outputs the binary data as the ON voltage -Von. Further, when the binary data for turning off the subfield is given, the booster circuit 540 outputs the binary data as a positive off voltage −Voff.
[0118]
FIG. 9 shows pixel write voltages in three consecutive subfield periods and changes in the subfield periods when the field inversion driving method is employed. FIG. 9A shows a case where continuous subfields are on, and FIG. 9B shows a case where continuous subfields are off. The example of FIG. 9 shows a case where the AC signal FR is at the H level.
[0119]
As shown in FIG. 9A, in the subfield period in which the transistor is turned on, the booster circuit 540 writes the on voltage + Von to the pixel. The ON voltage + Von gradually decreases in level toward the end of the subfield period due to leakage or the like. However, since the ON voltage + Von is set to a voltage sufficiently higher than the positive saturation voltage + Vsat, the voltage level applied to the pixel is higher than the positive saturation voltage + Vsat even at the end of the subfield period. . Therefore, it is possible to prevent the transmittance from changing due to leakage or the like.
[0120]
When the subfield is OFF, as shown in FIG. 9B, the booster circuit 540 writes the OFF voltage + Voff to the pixel. At this time, the off voltage + Voff is set to a voltage lower than the reference COM voltage. The off voltage + Voff gradually increases in level toward the end of the subfield period due to leakage or the like. However, since the off voltage + Voff is set to a voltage sufficiently lower than the positive threshold voltage + Vth, the voltage level applied to the pixel is lower than the positive threshold voltage + Vth even at the end of the subfield period. . Therefore, it is possible to prevent the transmittance from changing due to leakage or the like.
[0121]
Although FIG. 9 shows the state of the field period in which the alternating signal FR is at the H level, in the next field period, the alternating signal FR is at the L level, and the waveforms in FIGS. The polarity is reversed. Even in this case, it is obvious that the transmittance can be prevented from changing due to leakage or the like.
[0122]
FIG. 9 shows the case where continuous subfields are continuously on or off, but of course the above effect can be obtained even when these change for each subfield, and in each subfield period, The display is not adversely affected by voltage fluctuations.
[0123]
The booster circuit 540 boosts the binary data in accordance with the AC signal FR, and then supplies the binary data to the pixels of each line all at once. Thus, the data signals d1, d2, d3,..., Dn are simultaneously written in the pixels 110 in the first row counting from the top.
[0124]
In parallel with this writing, binary data for one row corresponding to the intersection with the second scanning line 112 from the top in FIG. 1 is latched dot-sequentially by the first latch circuit 520.
[0125]
Thereafter, the same operation is repeated until the scanning signal Gm corresponding to the m-th scanning line 112 is output. Note that the data signal written to the pixel 110 is held until writing in the next subfield Sf2.
[0126]
As described above, in this embodiment, the driving voltage (on voltage, off voltage) of the pixel is set in consideration of a sufficient margin for potential fluctuations such as capacitive coupling and leakage of the display device. Therefore, even when the surface inversion driving is performed in the subfield period or the field period, it is possible to prevent the transmittance from being changed due to the potential fluctuation, and it is possible to prevent the occurrence of flicker and the occurrence of in-plane display unevenness.
[0127]
In other words, in this embodiment, even when plane inversion driving is used, flicker and in-plane display unevenness can be prevented, and it is not necessary to use line inversion driving together. An electric field is not generated. Therefore, the black matrix provided between the pixels is not necessary in order to make the display defect due to the change in the alignment state between the adjacent pixels due to the horizontal electric field unnecessary, and the aperture ratio can be improved and high contrast can be realized.
[0128]
In the above embodiment, the example in which the polarity is inverted for each subfield or for each field has been described. However, it is obvious that the present invention can also be applied to the case where the polarity is inverted for a plurality of subfield units or a plurality of field units. is there.
[0129]
Next, the structure of the electro-optical device according to the above-described embodiments and application forms will be described with reference to FIGS. Here, FIG. 11 is a plan view showing the configuration of the electro-optical device 100, and FIG. 12 is a cross-sectional view taken along the line AA 'in FIG.
[0130]
As shown in these drawings, the electro-optical device 100 is configured such that the element substrate 101 on which the pixel electrode 118 and the like are formed and the counter substrate 102 on which the counter electrode 108 and the like are formed are separated from each other by a sealant 104. And a liquid crystal 105 as an electro-optical material is sandwiched in the gap. Actually, the sealing material 104 has a cut-out portion, and after the liquid crystal 105 is sealed through this, the sealing material 104 is sealed with a sealing material, but is omitted in these drawings.
[0131]
In the normally black display mode liquid crystal display device as in the present embodiment, for example, a vertical alignment film and a liquid crystal material having a negative dielectric anisotropy are combined to form a liquid crystal panel, and the transmission axis is They can be obtained by sandwiching them between two polarizing plates arranged 90 degrees apart.
[0132]
Of course, a TN mode liquid crystal which is a normally white display mode can also be used.
[0133]
The counter substrate 102 is a transparent substrate made of glass or the like. In the above description, the element substrate 101 is described as being made of a transparent substrate. However, in the case of a reflective electro-optical device, it may be a semiconductor substrate. In this case, since the semiconductor substrate is opaque, the pixel electrode 118 is formed of a reflective metal such as aluminum.
[0134]
In the element substrate 101, a light shielding film 106 is provided on the inner side of the sealant 104 and on the outer side of the display region 101a. In the region where the light shielding film 106 is formed, the scan driver 401 is formed in the region 130a, and the data driver 500 is formed in the region 140a.
[0135]
That is, the light shielding film 106 prevents light from entering the drive circuit formed in this region. A counter electrode voltage VLCCOM is applied to the light shielding film 106 together with the counter electrode 108.
[0136]
Further, in the element substrate 101, a plurality of connection terminals are formed outside the region 140a where the data driver 500 is formed and separated from the sealant 104, so that an external control signal, a power source, etc. Is input.
[0137]
On the other hand, the counter electrode 108 of the counter substrate 102 is electrically connected to the light shielding film 106 and the connection terminal in the element substrate 101 by a conductive material (not shown) provided in at least one of the four corners of the substrate bonding portion. Conduction is achieved. That is, the counter electrode voltage VLCCOM is applied to the light shielding film 106 via a connection terminal provided on the element substrate 101 and further to the counter electrode 108 via a conductive material.
[0138]
Further, according to the use of the electro-optical device 100, for example, in the case of the direct view type, the counter substrate 102 is first provided with a color filter arranged in a stripe shape, a mosaic shape, a triangle shape, or the like. 2 is provided with a light shielding film (black matrix) made of, for example, a metal material or resin. In the case of use of color light modulation, for example, when used as a light valve of a projector described later, a color filter is not formed. In the case of the direct view type, the electro-optical device 100 is provided with a light that irradiates light from the counter substrate 102 side or the element substrate side as required. In addition, an alignment film (not shown) that is rubbed in a predetermined direction is provided between the electrodes of the element substrate 101 and the counter substrate 102 to define the alignment direction of the liquid crystal molecules when no voltage is applied. On the other hand, a polarizer (not shown) corresponding to the orientation direction is provided on the counter substrate 102 side. However, if a polymer dispersed liquid crystal dispersed as fine particles in a polymer is used as the liquid crystal 105, the above-described alignment film, polarizer, and the like are not required, so that the light utilization efficiency is increased. This is advantageous in terms of low power consumption.
[0139]
In each of the above-described embodiments, the driving device is a pSi (polysilicon) TFT. However, the present invention is not limited to this. The present invention is a display element (liquid crystal in this embodiment) of an electro-optical device having a configuration similar to the above-described configuration, and the optical response time of the display element is longer than or close to the subfield time. It is applicable when having As such an electrical engineering apparatus, for example, a projector constituted by a liquid crystal light valve using pSi TFT as a driving device, or a direct-view liquid crystal display apparatus (direct-view LCD) using αSi (amorphous silicon) TFT or TFD as a driving device. ) Etc.
[0140]
As the electro-optic material, in addition to liquid crystal, an electroluminescence element or the like can be used for an apparatus that performs display by the electro-optic effect.
[0141]
In other words, the present invention can be applied to any electro-optical device having a configuration similar to the above-described configuration, in particular, any electro-optical device that performs gradation display using pixels that perform binary display that is on or off. It is.
[0142]
Next, some examples in which the above-described liquid crystal device is used in a specific electronic device will be described.
[0143]
First, a projector using the electro-optical device according to the embodiment as a light valve will be described. FIG. 13 is a plan view showing the configuration of the projector. As shown in this figure, in the projector 1100, a polarization illumination device 1110 is arranged along the system optical axis PL. In this polarization illumination device 1110, the light emitted from the lamp 1112 becomes a substantially parallel light beam as reflected by the reflector 1114, and enters the first integrator lens 1120. Thereby, the emitted light from the lamp 1112 is divided into a plurality of intermediate light beams. The divided intermediate light beam is converted into a single type of polarized light beam (s-polarized light beam) whose polarization directions are substantially uniform by a polarization conversion element 1130 having a second integrator lens on the light incident side, and the polarization illumination device The light is emitted from 1110.
[0144]
The s-polarized light beam emitted from the polarization illumination device 1110 is reflected by the s-polarized light beam reflection surface 1141 of the polarization beam splitter 1140. Of this reflected light beam, the blue light (B) light beam is reflected by the blue light reflecting layer of the dichroic mirror 1151 and modulated by the reflective electro-optical device 100B. Of the light beams transmitted through the blue light reflection layer of the dichroic mirror 1151, the red light (R) light beam is reflected by the red light reflection layer of the dichroic mirror 1152, and is modulated by the reflective liquid electro-optical device 100R. The
[0145]
On the other hand, among the light beams transmitted through the blue light reflection layer of the dichroic mirror 1151, the green light (G) light beam transmits through the red light reflection layer of the dichroic mirror 1152 and is modulated by the reflective electro-optical device 100G. .
[0146]
In this way, the red, green, and blue lights that have been color-light modulated by the electro-optical devices 100R, 100G, and 100B are sequentially synthesized by the dichroic mirrors 1152 and 1151, and the polarization beam splitter 1140, and then are projected by the projection optical system 1160. Is projected on the screen 1170. In addition, since the light beams corresponding to the primary colors of R, G, and B are incident on the electro-optical devices 100R, 100B, and 100G by the dichroic mirrors 1151, 1152, a color filter is not necessary.
[0147]
In the present embodiment, a reflective electro-optical device is used, but a projector using a transmissive display electro-optical device may be used.
[0148]
Next, an example in which the electro-optical device is applied to a mobile personal computer will be described. FIG. 14 is a perspective view showing the configuration of this personal computer. In the figure, a computer 1200 includes a main body 1204 provided with a keyboard 1202 and a display unit 1206. The display unit 1206 is configured by adding a front light to the front surface of the electro-optical device 100 described above.
[0149]
In this configuration, since the electro-optical device 100 is used as a reflection direct-view type, it is desirable that the pixel electrode 118 has irregularities so that the reflected light is scattered in various directions.
[0150]
Further, an example in which the electro-optical device is applied to a mobile phone will be described. FIG. 15 is a perspective view showing the configuration of this mobile phone. In the figure, a cellular phone 1300 includes the electro-optical device 100 along with a plurality of operation buttons 1302, an earpiece 1304, and a mouthpiece 1306.
[0151]
The electro-optical device 100 is also provided with a front light on the front surface as necessary. Also in this configuration, since the electro-optical device 100 is used as a reflection direct-view type, a configuration in which unevenness is formed in the pixel electrode 118 is desirable.
[0152]
In addition to the electronic devices described with reference to FIGS. 14 and 15, the electronic devices include a liquid crystal television, a viewfinder type, a monitor direct-view type video tape recorder, a car navigation device, a pager, an electronic notebook, a calculator, and a word processor. , Workstations, videophones, POS terminals, devices equipped with touch panels, and the like. Needless to say, the electro-optical devices according to the above embodiments and application forms can be applied to these various electronic devices.
[0153]
【The invention's effect】
As described above, according to the present invention, it is possible to improve the image quality by making it possible to avoid the influence of leakage or the like even when only the surface inversion driving is employed.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an electro-optical device according to a first embodiment of the invention.
FIG. 2 is a block diagram showing a specific configuration of a drive circuit 301 in FIG.
FIG. 3 is a graph for explaining control of multi-gradation display in the present embodiment.
4 is an explanatory diagram illustrating a specific configuration of a pixel in FIG. 1. FIG.
5 is a block diagram showing a specific configuration of a data driver 500 in FIG. 1. FIG.
FIG. 6 is an explanatory diagram for explaining an operation of the booster circuit 540;
7 is a graph for explaining a voltage generated by the drive voltage generation circuit 40 in FIG. 2;
FIG. 8 is an explanatory diagram for explaining a voltage generated by the drive voltage generation circuit 40 in FIG. 2;
FIG. 9 is a waveform diagram showing a driving voltage applied to a pixel in field inversion driving.
FIG. 10 is a timing chart for explaining the operation of the electro-optical device according to the present embodiment.
11 is a plan view showing the configuration of the electro-optical device 100. FIG.
12 is a cross-sectional view taken along line AA ′ in FIG.
FIG. 13 is a plan view showing a configuration of a projector.
FIG. 14 is a perspective view illustrating a configuration of a personal computer.
FIG. 15 is a perspective view illustrating a configuration of a mobile phone.
[Explanation of symbols]
10 ... Subfield timing generator
20 ... Memory controller
23, 24 ... Memory
30: Data encoder
31 ... ROM for code storage

Claims (6)

An on-voltage or threshold value equal to or higher than the saturation voltage of the electro-optic material for a display unit that is arranged in a matrix with the electro-optic material sandwiched therebetween and whose light transmittance is variable by voltage application. By supplying an off voltage equal to or lower than the voltage, subfield driving is performed to perform gradation expression according to the state and time ratio between the light transmission state and the non-transmission state in the unit time of the electro-optic material. In the electro-optical device for driving the pixel with each subfield divided into a plurality of fields on the time axis as a control unit,
Latch means for latching binary data for designating a subfield for applying the on-voltage and a subfield for applying the off-voltage based on display data;
Surface inversion driving is performed by applying a positive voltage having a higher potential than a predetermined reference potential or a negative voltage having a lower potential to each pixel for each inversion driving period which is a plurality of subfield periods or field periods, and In the inversion driving period, the difference between the on-voltage and the saturation voltage of the electro-optic material is set so that the voltage applied to the pixel does not become equal to or lower than the saturation voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. In addition, the voltage applied to the pixel is set to be not less than the threshold voltage of the electro-optic material due to the influence of the coupling capacitance or charge leakage. In addition, the difference between the off voltage and the threshold voltage of the electro-optic material is generated in the voltage applied to the pixel in the inversion driving cycle for the pixel. That is set to more potential variation amount, anda pixel drive means for applying to the pixel converts the binary data to which the latching means is latched in the ON voltage or OFF voltage,
The electro-optical device, wherein the pixel driving unit sets the off voltage to a voltage having a polarity opposite to a driving polarity in an inversion driving cycle and an absolute value smaller than an absolute value of the threshold voltage.   The pixel driving unit sets the ON voltage to be higher than the saturation voltage by the potential fluctuation amount during the positive driving period of the inversion driving cycle, and sets the OFF voltage to the potential fluctuation amount from the threshold voltage. In the negative drive period of the inversion drive cycle, the ON voltage is set lower than the saturation voltage by the potential fluctuation amount or more, and the OFF voltage is set by the potential fluctuation amount or more than the threshold voltage. The electro-optical device according to claim 1, wherein the electro-optical device is set high. The electro-optical device according to claim 1, wherein the inversion driving cycle is a multiple field cycle.   The electro-optical device according to claim 1, wherein the pixel driving unit sets the ON voltage to a value that is 1.5 times the saturation voltage. An on-voltage or threshold value equal to or higher than the saturation voltage of the electro-optic material for a display unit that is arranged in a matrix with the electro-optic material sandwiched therebetween and whose light transmittance is variable by voltage application. By supplying an off voltage equal to or lower than the voltage, subfield driving is performed to perform gradation expression according to the state and time ratio between the light transmission state and the non-transmission state in the unit time of the electro-optic material. In the driving method of the electro-optical device for driving the pixel by using each subfield obtained by dividing the field into a plurality on the time axis as a control unit,
A latch procedure for latching binary data that designates a subfield to which the on-voltage is applied and a subfield to which the off-voltage is applied based on display data;
Surface inversion driving is performed by applying a positive voltage having a higher potential than a predetermined reference potential or a negative voltage having a lower potential to each pixel for each inversion driving period which is a plurality of subfield periods or field periods, and In the inversion driving cycle, the difference between the on-voltage and the saturation voltage is inverted with respect to the pixel so that the voltage applied to the pixel does not become lower than the saturation voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. The voltage applied to the pixel in the driving cycle is set to be greater than the amount of potential fluctuation, and the voltage applied to the pixel does not exceed the threshold voltage of the electro-optic material due to the influence of coupling capacitance or charge leakage. The difference between the off voltage and the threshold voltage is equal to or greater than the amount of potential fluctuation that occurs in the voltage applied to the pixel in the inversion driving cycle for the pixel. Constant to, it includes a pixel driving procedure converts the binary data latched in the ON voltage or the OFF voltage is applied to the pixel in the latch procedure,
In the pixel driving procedure, the off-voltage is set to a voltage having a polarity opposite to that of the driving polarity of the inversion driving cycle and an absolute value smaller than the absolute value of the threshold voltage. Method. Electronic apparatus, characterized by comprising an electro-optical device according to any one of claims 1 to 4.

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