JP4092880B2 - Electro-optical device, drive circuit, and electronic device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an electro-optical device, a driving circuit, and an electronic apparatus that contribute to simplification of configuration and low power consumption.
[0002]
[Prior art]
In recent years, electro-optical devices that perform display by electro-optical changes in electro-optical materials such as liquid crystal and organic EL (electroluminescence) have been used as various information processing equipment and televisions as display devices that replace cathode ray tubes (CRT). It is being used widely.
Here, the electro-optical device can be roughly classified into an active matrix type in which pixels are driven by switching and a passive matrix type in which pixels are driven without using a switching element. Among these, the active matrix type electro-optical device according to the former has the following configuration.
[0003]
That is, in the active matrix type electro-optical device, pixel electrodes are formed corresponding to the intersections of the scanning lines extending in the row direction and the data lines extending in the column direction. A switching element such as a thin film transistor that is turned on and off according to a scanning signal supplied to the scanning line is interposed between the pixel line and the data line, and a counter electrode is opposed to the pixel electrode via an electro-optic material. Yes.
[0004]
In such a configuration, when an on-voltage scanning signal is applied to a scanning line, a switching element connected to the scanning line is turned on. When a data signal corresponding to the gradation (density) is applied to the pixel electrode through the data line in the ON state, the electro-optical material sandwiched between the pixel electrode and the counter electrode A voltage corresponding to the data signal is applied. For this reason, as a result of the electro-optic substance changing electro-optically, the transmitted light amount, reflected light amount or light emission amount (in any case, the light amount visually recognized by the observer) is applied to the pixel signal. Depending on. Therefore, it is possible to perform a predetermined display by executing the operation for applying the data signal to the pixel electrode for each pixel.
[0005]
By the way, for such an electro-optical device, the signal / data for instructing the gradation of the pixel may basically be either analog or digital. However, in recent years, the signal / data has deteriorated during various arithmetic processes. In many cases, it is digital for reasons such as not occurring. Therefore, in this case, the electro-optical device has a configuration in which digital gradation data indicating the gradation of the pixel is appropriately processed by the data line driving circuit and converted into a data signal, and the data signal is supplied to the data line. Become.
[0006]
Here, a signal line (data bus) that supplies digital gradation data to the electro-optical device has a considerable parasitic capacitance. For this reason, whenever a bit of gradation data changes, the parasitic capacitance is charged / discharged by the amplitude of the logic level, so that power is wasted in the signal line.
On the other hand, in the data line driving circuit, as the number of bits of gradation data increases, the configuration becomes complicated and the switching operation of various active elements is frequently performed, so that power consumption tends to increase. In particular, in the method of supplying the image signal to the pixel electrode after being modulated with the pulse width indicated by the gradation data, a pulse train with a very short interval corresponding to the number of gradations is required, which increases power consumption. Becomes prominent.
[0007]
For this reason, among the m-bit gradation data, the lower (mn) bits are discarded while leaving the upper n bits, and the electro-optical device displays the gradation according to the upper n-bit gradation data. Was proposed. In this technique, the number of signal lines for supplying grayscale data is reduced from m to n, so that the power consumed by the parasitic capacitance of the signal lines is reduced and the configuration of the data line driving circuit is accordingly increased. It will be simplified.
[0008]
[Problems to be solved by the invention]
However, in the technology that supplies only the upper n bits of the m-bit gradation data to the electro-optical device, information that should be originally is discarded, so that the original image indicated by the m-bit gradation data, There is a problem that not only the error with the image displayed by the electro-optical device is increased, but also the difference between gradations is increased, resulting in a striped pattern and a deterioration in display quality. .
[0009]
The present invention has been made in view of the above-described circumstances, and an object of the present invention is to reduce the display quality and to simplify the configuration of the electro-optical device and reduce the power consumption. An object is to provide an apparatus, a driving circuit, and an electronic device.
[0010]
[Means for Solving the Problems]
  In general, when a person visually recognizes light, the resolution for light intensity in the spatial frequency domain is high, but the resolution for color difference is low. In this case, about 60% of the light intensity is determined by the brightness of G (green).
  Therefore, paying attention to these, the electro-optical device according to the present invention is provided at the intersection of the scanning line and the data line, and the data signal supplied to the data line when the scanning line is selected. This is an electro-optical device that associates sub-pixels with corresponding gradations with red (R), green (G), and blue (B), and performs color display of one pixel by three RGB sub-pixels. In addition, a data signal based on the R gradation data is commonly supplied to the R subpixels belonging to each of the two pixels adjacent to each other in either the horizontal scanning direction or the vertical scanning direction, and the two adjacent pixels are also adjacent to each other. A data signal based on the B gradation data is commonly supplied to each of the B subpixels belonging to the pixel, while a data signal based on the G gradation data is supplied to each pixel for the G subpixel.When the supplied gradation data is m bits for each of RGB, if the difference between the RGB gradation data in two adjacent pixels is equal to or greater than a threshold value, R or R belonging to the two pixels Without supplying a common data signal based on R or B gradation data to each of the B sub-pixels, the upper n ( n is an integer satisfying n <m and satisfying 3n ≦ 2m).It is characterized by that.
  According to this configuration, the G gradation data having a large influence when determining the light intensity is supplied for each pixel, but the R (red) and B (blue) gradation data having a small influence are supplied. Since two adjacent sub-pixels are supplied in common, the gradation data that must be supplied simultaneously is reduced to 2/3. Therefore, since the number of signal lines for supplying grayscale data can be reduced, the power consumed by the parasitic capacitance of the signal lines is reduced, and the configuration for driving the data lines is simplified accordingly. The power consumed by this configuration is also reduced. On the other hand, although two RB sub-pixels are shared, the number of bits has not decreased, so there is no increase in the difference between gradations. Occurrence is suppressed and display quality is not lowered.
  On the other hand, blurring may occur when the color difference or gradation change between pixels is large. In this configuration, the difference between the RGB gradation data in two adjacent pixels is greater than or equal to the threshold value. If so, RGB gradation data is provided for each pixel, so that the occurrence of blurring is suppressed. In this configuration, it is considered that a pattern is generated as the lower bits are discarded. However, the RGB gradation data is given to each pixel when the color difference or gradation change between pixels is originally large. Therefore, these patterns should be difficult to see in practice.
  In the present invention, the data signal supplied commonly to the sub-pixels belonging to each of the two adjacent pixels is the gradation data corresponding to each of the sub-pixels belonging to the two pixels, or an average value thereof. A configuration that is based is preferred.
[0012]
In the present invention, R subpixels belonging to each of two adjacent pixels are combined into one, and B subpixels belonging to each of the two adjacent pixels are combined into one. A configuration is preferred. According to this configuration, the number of output terminals in the circuit for driving the data line is reduced and the total number of sub-pixels is reduced by the amount of the two R (or B) sub-pixels combined into one. Become.
In such a configuration, it is desirable that the combined area of the R subpixels and the combined area of the B subpixels are approximately twice the area of the G subpixel. As a result, the ratio of the gap between the sub-pixels is reduced, so that the aperture ratio can be improved.
[0013]
Furthermore, since the electronic apparatus according to the present invention includes the electro-optical device, it is possible to simplify the configuration, reduce power consumption, and the like while suppressing deterioration in display quality. Note that examples of such an electronic device include a mobile personal computer, a digital still camera, a mobile phone, and the like that are extremely demanded for low power consumption.
[0014]
  The present invention can also be realized as a drive circuit for an electro-optical device. That is, in the driving circuit of the electro-optical device according to the present invention, the sub-pixels provided at the intersections of the scanning lines and the data lines are assigned to red (R), green (G), and blue (B), respectively. A driving circuit which is used in an electro-optical device that performs color display of one pixel by three RGB sub-pixels and supplies a data signal to the sub-pixel corresponding to the selected scanning line via the data line In addition, a data signal based on R gradation data is commonly supplied to R sub-pixels belonging to each of two pixels adjacent to each other in either the horizontal scanning direction or the vertical scanning direction. A data signal based on B gradation data is commonly supplied to each of the B subpixels belonging to two pixels, while a data signal based on the G gradation data is supplied to each pixel for the G subpixel. SupplyIn the first mode, G gradation data is supplied, and R gradation data and B gradation data are alternated for each pixel. On the other hand, in the second mode, the RGB grayscale data is provided by being provided for each signal line and the signal line supplied by reducing the number of bits in the first mode. A conversion circuit that converts grayscale data into a data signal and supplies the data signal to the corresponding data line, and the signal in the first mode in which R grayscale data is supplied to the signal line. G gradation data supplied to the line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled to obtain the pixel column. R data line belonging to and adjacent to the pixel column Are supplied in common to conversion circuits corresponding to each of the R data lines belonging to the pixel column, and during the period in which the B grayscale data is supplied to the signal lines, the G level supplied to the signal lines is supplied. The tone data is sampled and supplied to the conversion circuit corresponding to the G data line belonging to the other pixel column, and the B gradation data is sampled to obtain the B data line belonging to the pixel column. In addition, in the second mode, R or B belonging to two adjacent pixels is supplied in common to the conversion circuit corresponding to each of the B data lines belonging to the pixel column adjacent to the pixel column. Rather than commonly supplying data signals based on R or B gradation data to each of the sub-pixels, the RGB gradation data supplied to the signal line is respectively supplied to a certain pixel column. Of data lines belonging to And a mechanism for supplying the conversion circuits corresponding toIt features a configuration. According to this configuration, as with the electro-optical device, it is possible to simplify the configuration, reduce power consumption, and the like while suppressing a reduction in display quality.In addition, since the first or second mode can be selected according to the display content, it is possible to achieve both prevention of deterioration in display quality and reduction in power consumption.
[0015]
  As a specific aspect of such a drive circuit, the following first to second4The modes up to are conceivable. Among these, the first mode is a G signal line to which G gradation data is supplied, an RB signal line to which R gradation data and B gradation data are alternately supplied for each pixel, and data A conversion circuit which is provided for each line and converts the supplied gradation data into a data signal and supplies the data signal to the corresponding data line; and during the period in which the R gradation data is supplied to the RB signal line The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. While supplying in common to the conversion circuit corresponding to each of the R data line belonging to the pixel column and the R data line belonging to the pixel column adjacent to the pixel column, B gradation data is supplied to the RB signal line. The G floor supplied to the G signal line during the supplied period The data is sampled and supplied to the conversion circuit corresponding to the G data line belonging to the other pixel column, and the B gradation data is sampled to obtain the B data line belonging to the pixel column; A register that is commonly supplied to the conversion circuit corresponding to each of the B data lines belonging to the pixel column adjacent to the pixel column is configured. According to the first aspect, since the total number of signal lines is reduced, the configuration can be simplified and the power consumption can be reduced.
[0016]
Next, in the second mode, an R signal line to which R gradation data is supplied, a G signal line to which G gradation data is supplied, and a B signal line to which B gradation data is supplied. A conversion circuit that is provided for each data line, converts the supplied gradation data into a data signal, and supplies the data signal to the corresponding data line; and a period in which the R gradation data is supplied to the R signal line The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. The R data line belonging to the pixel column and the R data line belonging to the pixel column adjacent to the pixel column are commonly supplied to the conversion circuit, and the B signal line is supplied with the B gradation. During the period in which data is supplied, the G grayscale data supplied to the G signal line is And B to the conversion circuit corresponding to the G data line belonging to the other pixel column, and sampling the B gradation data to obtain the B data line belonging to the pixel column; A register that is commonly supplied to the conversion circuit corresponding to each of the B data lines belonging to the pixel column adjacent to the pixel column is configured. In the second mode, the total number of signal lines is not reduced as compared with the first mode, but, for example, the B gray level data is unnecessary in the period in which the R gray level data is supplied. Therefore, it is not necessary to shift the B gradation data from the previous period. For this reason, the power consumed by the parasitic capacitance of the image signal line can be reduced accordingly.
[0017]
Further, according to a third aspect, a G signal line to which G gradation data is supplied, an RB signal line to which R gradation data and B gradation data are alternately supplied for each pixel, G is provided for each data line, while R or B is provided for every two data lines belonging to adjacent pixel columns, and the supplied grayscale data is converted into a data signal, and data A conversion circuit for converting the signal into a line, and sampling the G gradation data supplied to the G signal line during a period in which the R gradation data is supplied to the RB signal line, to a certain pixel column The R gradation data is supplied to the conversion circuit corresponding to the G data line to which the signal belongs, and the R data line belonging to the pixel column and the R data line paired therewith are sampled. While supplying to the corresponding conversion circuit, the RB signal line has B During the period when the tone data is supplied, the G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to the other pixel column; The B grayscale data is sampled, and the B data line belonging to the pixel column and a register supplied to the conversion circuit corresponding to the B data line paired with the B data line are included. It is. In the third aspect, similarly to the second aspect, the power consumed by the parasitic capacitance of the signal line can be suppressed.
[0018]
According to a fourth aspect, in the horizontal scanning period in which the G signal line to which the G gradation data is supplied and either one of the odd-numbered or even-numbered scanning lines is selected, the R gradation data In the horizontal scanning period in which one of the other scanning lines is selected, the RB signal line to which the B gradation data is supplied and the gradation data provided for each data line are used as the data. A conversion circuit that converts the signal into a corresponding data line and converts the grayscale data supplied to the G signal line to a corresponding G data line belonging to a certain pixel column The circuit is supplied in the horizontal scanning period in which the one scanning line is selected, and the R gradation data supplied to the RB signal line is sampled until the selection of the next scanning line is completed. R data belonging to the pixel column for a period The G scanning data supplied to the G signal line is sampled, and the other scanning line is connected to the conversion circuit corresponding to the G data line belonging to the pixel column. In addition to being supplied in the selected horizontal scanning period, the B gradation data supplied to the RB signal line is sampled and held for the period until the selection of the next scanning line is completed, And a mechanism for supplying a conversion circuit corresponding to the B data line to which the data line belongs. According to the fourth aspect, compared to the first, second, and third aspects, the number of registers for sampling gradation data and the number of conversion circuits can be reduced. Simplification and low power consumption can be achieved.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0021]
<First Embodiment>
First, the electro-optical device according to the first embodiment of the present invention will be described taking as an example a type using liquid crystal as an electro-optical material. FIG. 1 is a block diagram showing the configuration of the electro-optical device.
As shown in this figure, in the electro-optical device 100, a plurality of m scanning lines 112 are formed extending in the row (X) direction, while a plurality of (3 · n) data lines 114 are formed. , Extending in the column (Y) direction (m and n are plural). Then, R (red), G (green), and B (blue) sub-pixels 120 are arranged corresponding to the intersection positions of the scanning lines 112 and the data lines 114, respectively.
[0022]
Here, one pixel having a substantially square shape is formed by three of the R, G, and B sub-pixels 120 adjacent to each other in the row direction. That is, the resolution of the electro-optical device 100 is vertical m × horizontal n pixels. Note that the order of arrangement of the sub-pixels is not limited to the order of RGB, but is arbitrary.
Also, in the electro-optical device 100, a sub-pixel of a certain color has 64 (= 2 according to 6-bit gradation data.⁶) Gradation is displayed. Accordingly, in this electro-optical device 100, 260,000 colors (= 2) are considered for one pixel.^{6 × Three}) Will be displayed in color.
[0023]
Here, as shown in FIG. 2A, the sub-pixel 120 corresponds to a portion where the scanning line 112 and the data line 114 intersect with each other (electrically insulated portion). Thin film transistor (hereinafter referred to as “TFT”) 116 is provided, its gate is connected to the scanning line 112, its source is connected to the data line 114, and its drain is connected to the pixel electrode 118 and one end of the storage capacitor 119. It is connected to the. In this embodiment, if the TFT 116 is an N-channel type, when the scanning signal supplied to the scanning line 112 becomes H level, the TFT 116 is turned on between the source and the drain.
[0024]
On the other hand, the pixel electrode 118 is opposed to the counter electrode 108 to which a constant voltage is applied. A liquid crystal capacitance is formed by both electrodes and the liquid crystal 105 sandwiched between both electrodes, and the amount of transmitted light changes according to the effective voltage value applied between both electrodes. .
Note that the counter electrode 108 is common to all the sub-pixels 120 in this embodiment. Further, the other end of the storage capacitor 119 is common to all the sub-pixels 120.
[0025]
Returning to FIG. 1 again, the scanning line driving circuit 130 supplies scanning signals to the m scanning lines 112, respectively. Specifically, as shown in FIG. 5, the scanning line driving circuit 130 latches the pulse signal DY defining the start of the vertical scanning period at the rising edge of the clock signal YCK, and the latched signal is clock signal YCK. Are sequentially delayed every one cycle (corresponding to one horizontal scanning period) and supplied as scanning signals Y1, Y2, Y3,..., Ym to the scanning lines 112 from the first row to the m-th row, respectively. It is. For this reason, only one of the scanning signals Y1, Y2, Y3,..., Ym becomes the H level for one horizontal scanning period (1H). Therefore, in this description, the scanning line 112 supplied with the scanning signal at the H level is particularly referred to as a selected scanning line or a selected scanning line.
[0026]
On the other hand, the data line driving circuit 140 supplies a data signal corresponding to the density (gradation) of the sub-pixel 120 located on the selected scanning line via the data line 114. Here, in order to generally describe the column direction, if j (j is an integer satisfying 1 ≦ j ≦ n) is used, the (3j-2) th column, the (3j-1) th column, and (3j) Data signals supplied to the data line 112 in the column are denoted as Rj, Gj, and Bj, respectively. That is, it is assumed that the data signals Rj, Gj, and Bj are supplied to the R, G, and B sub-pixels 120 that constitute the pixel in the jth column, respectively.
[0027]
Here, details of the data line driving circuit 140 will be described. FIG. 3 is a block diagram showing a configuration of the data line driving circuit 140. In this figure, the shift register 1410 sequentially shifts the pulse signal DX supplied at the beginning of the horizontal scanning period every time the clock signal XsCK rises, and outputs it as sampling control signals Xs1, Xs2, Xs3,..., Xsn. Is.
[0028]
Next, in the present embodiment, the gradation data DR, DG, DB corresponding to each of R, G, B is supplied from the host device (not shown) at the timing shown in FIG. That is, the gradation data DG is supplied for each pixel via a signal line (data bus) 142, while the gradation data DR and DB are alternately supplied via the signal line 144 every other pixel. The
For this reason, the gradation data DR (DB) that is actually supplied is one that takes into account the omitted gradation data DR (DB). Specifically, one of the original gradations of the sub-pixels in the two pixels or a value calculated so as to have an average value thereof is supplied to the data line driving circuit 140.
[0029]
Subsequently, the register (Reg) 1420 is provided in one-to-one correspondence with the data line 114, and samples the gradation data supplied to the connected signal line 142 or 144 at the rising edge of the sampling control signal. And hold it. Generally, the register 1420 corresponding to the data line 114 to which the data signal Gj is supplied is connected to the signal line 142, while the register 1420 corresponding to the data line 114 to which the data signals Rj and Bj are supplied is Are connected to the signal line 144. Further, if j is generally an odd number, the sampling control signal Xsj corresponding to the pixels in the j column is divided into three registers 1420 corresponding to the data lines 114 to which the data signals Rj, Gj, and R (j + 1) are supplied. On the other hand, the sampling control signal Xs (j + 1) corresponding to the pixels in the subsequent even (j + 1) column is supplied to the register corresponding to the data line 114 to which the data signals Bj, G (j + 1), B (j + 1) are supplied. Three of 1420 are supplied.
[0030]
Next, the latch circuit 1430 is provided in one-to-one correspondence with the register 1420, and latches the gradation data held by the corresponding register 1420 at the rising edge of the latch pulse LP supplied at the start of the horizontal scanning period. Output.
The conversion circuit 1440 is provided in a one-to-one correspondence with the latch circuit 1430, and converts the grayscale data latched by the corresponding latch circuit 1430 into an analog signal having the polarity indicated by the signal AK, thereby generating a data line. 114 is supplied. Here, the polarity indicated by the signal AK is based on the voltage applied to the counter electrode 108 (or a voltage near this), and the higher side than the voltage is positive and the lower side is negative. It is said.
[0031]
<Operation>
Next, the operation of the electro-optical device according to this embodiment will be described. Here, FIG. 5 is a timing chart for explaining the operation in the row (Y) direction in the electro-optical device, and FIG. 6 is a timing chart for explaining the operation in the column (X) direction.
[0032]
First, as shown in FIG. 5, when the pulse signal DY is supplied at the start of the vertical scanning period and the clock signal YCK rises, the scanning line driving circuit 130 sets the scanning signal Y1 to the H level. Therefore, the TFT 116 is turned on over all the sub-pixels 120 located at the intersection of the scanning lines 112 in the first row.
[0033]
On the other hand, on the column (X) direction side, as shown in FIG. 6, prior to the period when the scanning signal Y1 is at the H level, the pixels in the first row, first column, first row, second column,. Corresponding gradation data is supplied in order. Specifically, the gradation data DG and DR are supplied corresponding to the pixels in the odd columns, and the gradation data DG and DB are supplied to the pixels in the even columns.
[0034]
Among these, when the sampling control signal Xs1 becomes H level by the shift register 1410 during the period in which the gradation data DG and DR are supplied corresponding to the pixel in the first row and the first column, the gradation data DG The gradation data DR is shared by two of the registers 1420 corresponding to the data lines 114 to which the data signals R1 and R2 are supplied, while being individually sampled by the register 1420 corresponding to the data line 114 to which the G1 is supplied. Is sampled.
Next, when the sampling control signal Xs2 becomes H level during the period in which the gradation data DG and DB are supplied corresponding to the pixels in the first row and the second column, the gradation data DG is supplied with the data signal G2. The grayscale data DB is sampled in common by two of the registers 1420 corresponding to the data lines 114 to which the data signals B1 and B2 are supplied, while being individually sampled by the register 1420 corresponding to the data line 114. .
[0035]
Similarly, when the sampling control signal of the corresponding column becomes H level during the period in which the gradation data DG and DR are supplied corresponding to the pixels of the odd column, the gradation data DG is While the grayscale data DR is sampled independently by the register 1420 corresponding to G, the gradation data DR is obtained by the register 1420 corresponding to R of the pixel and the register 1420 corresponding to R of the pixel located one column after the pixel. The two are sampled in common.
Also, when the sampling control signal of the corresponding column becomes H level during the period in which the gradation data DG and DB are supplied corresponding to the pixels in the even number column following the odd number, the gradation data DG is On the other hand, the gradation data DB is sampled by the register 1420 corresponding to G of the pixel, while the register 1420 corresponding to B of the pixel and the register 1420 corresponding to B of the pixel located one column before the pixel. Are commonly sampled by the two.
Such an operation is repeated until the gradation data corresponding to the pixel in the 1st row and the nth column is held in the register 1420 corresponding to the data line 114 in the last column.
[0036]
When the gradation data is held in the register 1420 corresponding to the data line 114 in the last column, the latch pulse LP is output in accordance with the timing when the scanning signal becomes H level. Therefore, the gradation data held in the registers 1420 corresponding to the respective columns are latched all at once by the latch circuit 1430. Further, the latched gradation data is converted into an analog signal by the conversion circuit 1440 and supplied to the data line 114 as a data signal.
For this reason, in the sub-pixel 120 located in the first row, when the TFT 116 is turned on, charges corresponding to the voltage of the data signal are accumulated in the pixel electrode 118 (and the storage capacitor 119), respectively. .
A similar operation is performed line-sequentially for the sub-pixels 120 located in the second row, the third row,. As a result, charges corresponding to the data signals obtained by converting the gradation data are accumulated in the pixel electrodes 118 of all the sub-pixels 120, respectively.
Note that the same operation is performed in the next vertical scanning period. However, in the next vertical scanning period, in the case of one sub-pixel 120, the data signal is output with the polarity inverted from the previous vertical scanning period in accordance with the instruction of the signal AK. For this reason, the liquid crystal capacitor is AC driven and no DC component is applied.
[0037]
As described above, according to the electro-optical device according to the embodiment, the G sub-pixel has the gradation individually designated for each pixel, but the R sub-pixel in two pixels adjacent to each other in the horizontal scanning direction. Have the same gradation, and similarly, the B sub-pixels also have the same gradation. In addition, the R and B sub-pixels have densities in consideration of the original gradation in two pixels adjacent to each other in the horizontal scanning direction.
Here, when a person visually recognizes light, the resolution for the light intensity in the spatial frequency domain is high, but the resolution for the color difference is low, and about 60% of the light intensity is determined by the brightness of G (green). . For this reason, even if the gradations of the R and B sub-pixels are the same in the two pixels, the gradation of the G sub-pixel is different for each pixel, so that it is difficult to be visually recognized as a deterioration in display quality.
On the other hand, in this embodiment, the 6-bit gradation data DG is supplied for each pixel via the signal line 142, and the 6-bit gradation data DR and the 6-bit gradation data DB are transmitted via the signal line 144. Are alternately supplied every other pixel. For this reason, the number of lines required for the signal lines 142 and 144 is only 12 although a total of 18-bit gradation data is required. For this reason, in this embodiment, it is possible to reduce the amount of power that is wasted due to the parasitic capacitance of the signal lines 142 and 144.
[0038]
<Modification of First Embodiment>
By the way, the electro-optical device according to the above-described embodiment uses the point that the gradation data DR and DB are alternately supplied every other pixel when the two pixels adjacent to each other in the horizontal scanning direction are shared. Although the signal line 144 is shared, the grayscale data DR and DB can be shared in the two pixels without sharing the signal line 144.
The electro-optical device according to the above-described embodiment samples the gradation data DR first when the gradation data DR and DB are shared by two pixels adjacent to each other in the horizontal scanning direction. Although the gradation data DB is sampled, the sampling timing may be reversed.
[0039]
Therefore, as a modification of the first embodiment, a configuration in which the gradation data DR and DB are respectively input via dedicated signal lines and the timing for sampling the gradation data DR and DB is switched will be described. FIG. 7 is a block diagram showing the configuration of the modified data line driving circuit 140.
The data line driving circuit 140 shown in FIG. 7 is different from the configuration shown in FIG. 3 in that first, the grayscale data DR and DB are supplied via the signal lines 146 and 148, respectively. Second, the relationship between the sampling control signals Xs1, Xs2, Xs3,..., Xsn supplied to the register 1420 is different.
[0040]
Of these, the first point will be described in detail. In this modified configuration, the gradation data DG is the same as that of the first embodiment in that the gradation data DG is supplied via the signal line 142 for each pixel. DR differs from the first embodiment in that DR is supplied via the signal line 146 every other pixel, and the gradation data DB is supplied via the signal line 148 every other pixel.
[0041]
Next, the second point will be described in detail. Generally, if j is an odd number, the sampling control signal Xsj corresponding to the pixels in the j column is data supplied with data signals Rj, Gj, R (j + 1). While supplied to three of the registers 1420 corresponding to the line 114, the sampling control signal Xs (j + 1) corresponding to the subsequent even (j + 1) column of pixels is supplied with the data signals B (j + 1), G (j + 1), B ( j + 2) is supplied to three of the registers 1420 corresponding to the supplied data line 114. However, as an exception, the pulse signal DX is supplied to the register 1420 corresponding to the data line 114 to which the data signal B1 is supplied.
[0042]
Regarding the operation of this modified configuration, the supply timings of the gradation data DR and DB are replaced with those in the first embodiment (see FIG. 6). Specifically, as shown in FIG. 8, the gradation data DB corresponding to the pixels in the first column is supplied at the rising timing of the signal DX before the rising of the sampling control signal Xs1. Therefore, the gradation data DB is held in the register 1420 corresponding to the data line 114 to which the data signal B1 is supplied.
Next, the gradation data DR and DG corresponding to the pixels in the first column are supplied at the rising timing of the sampling control signal Xs1. For this reason, the gradation data DR is sampled in common by two registers 1420 corresponding to the data lines 114 to which the data signals R1 and R2 are supplied, while the gradation data DG is supplied by the data signal G1. It is sampled independently by the register 1420 corresponding to the data line 114 to be processed.
Further, the gradation data DG and DB corresponding to the pixels in the second column are supplied at the rising timing of the sampling control signal Xs2. Therefore, the gradation data DG is independently sampled by the register 1420 corresponding to the data line 114 to which the data signal G2 is supplied, while the gradation data DB is the data to which the data signals B2 and B3 are supplied. Sampled in common by two of the registers 1420 corresponding to line 114.
[0043]
Thereafter, similarly, the gradation data DR and DG corresponding to the pixels in the column are supplied at the rising timing of the sampling control signal corresponding to the pixels in the odd column. For this reason, the gradation data DR is sampled in common by the register 1420 corresponding to R of the pixel and the register 1420 corresponding to R of the pixel located one column later, The gradation data DG is independently sampled by the register 1420 corresponding to G of the pixel.
Also, when the sampling control signal of the corresponding column becomes H level during the period in which the gradation data DG and DB are supplied corresponding to the pixels in the even number column following the odd number, the gradation data DG is The grayscale data DB is sampled by the register 1420 corresponding to G of the pixel, while the register 1420 corresponding to B of the pixel and the register 1420 corresponding to B of the pixel located one column after the pixel Are commonly sampled by the two.
[0044]
The subsequent operations in this modified configuration are the same as those in the first embodiment. That is, when the gradation data is held in the register 1420 corresponding to the data line 114 in the last column, the latch pulse LP is output at the timing when the scanning signal becomes H level, and each sampled gradation data is output. Are simultaneously latched by the latch circuit 1430, are further converted into analog signals by the conversion circuit 1440, and are supplied to the data line 114 as data signals.
[0045]
In such a modified configuration, the number of signal lines 142, 146, and 148 is the same as that of the first embodiment as compared with the first embodiment, but when a person determines the brightness, the number of signal lines 142, 146, and 148 is less affected. The gradation data DR and DB supplied to the R and B sub-pixels that are not present are shared by two adjacent pixels. Therefore, changes in the gradation data DR and DB supplied to the signal lines 146 and 148 appear every two pixels as shown in FIG.
For this reason, according to the modified configuration, since the frequency of charging / discharging performed by the parasitic capacitance is reduced as compared with the conventional configuration in which changes occur for each pixel, the power consumed by the parasitic capacitance is displayed accordingly. It is possible to eliminate it while suppressing the deterioration of quality.
[0046]
Second Embodiment
Next, an electro-optical device according to a second embodiment of the invention will be described. The electro-optical device according to the second embodiment is different from the first embodiment only in the configuration of the data line driving circuit 140. Therefore, the data line driving circuit 140 according to the second embodiment will be mainly described.
[0047]
FIG. 9 is a block diagram showing a configuration of the data line driving circuit 140 in the second embodiment. In the data line driving circuit 140 shown in this figure, generally, if j is an odd number, it corresponds to the data line 114 to which the data signals Rj, Gj, G (j + 1), B (j + 1) are supplied. Thus, a set of a register 1420, a latch circuit 1430, and a conversion circuit 1440 is provided, but not provided on the data line 114 to which the data signals Bj and R (j + 1) are supplied.
However, the output of the conversion circuit 1440 corresponding to the data signal B (j + 1) is also connected to the data line 114 corresponding to the data signal Bj, and the output of the conversion circuit 1440 corresponding to the data signal Rj is the data signal R It is also connected to the data line 114 corresponding to (j + 1).
That is, in the present embodiment, the conversion circuit 1440 corresponding to the R sub-pixel among the pixels in the j-th column outputs the data signals Rj and R (j + 1) in common, while the pixels in the (j + 1) -th column. Among them, the conversion circuit 1440 corresponding to the B sub-pixel is configured to output the data signals Bj and B (j + 1) in common.
[0048]
As described above, according to the electro-optical device according to the second embodiment, similar to the first embodiment, the gradations supplied to the R and B sub-pixels that do not significantly influence the brightness when the person determines the brightness. Since the data DR and DB are shared in consideration of two adjacent pixels, only 12 lines are required for the signal lines 142 and 144. For this reason, in the second embodiment, it is possible to suppress the power consumed by the parasitic capacitance of the signal lines 142 and 144 while suppressing the deterioration of the display quality.
Furthermore, in the second embodiment, a set of the register 1420, the latch circuit 1430, and the conversion circuit 1440 generally corresponds to the data line 114 to which the data signals Bj and R (j + 1) are supplied if j is an odd number. Therefore, the configuration of the data line driver circuit 140 can be simplified, and power consumption can be reduced due to the simplified configuration.
In the second embodiment, similar to the modification in the first embodiment, the gradation data DR, DG, and DB may be input via dedicated signal lines, or the sampling timings of R and B are switched. May be.
[0049]
<Third Embodiment>
In the first and second embodiments described above, in two pixels adjacent to each other in the horizontal scanning direction, when the R and B sub-pixels have the same gradation, a common data signal is sent to each different data line. 114.
However, the configuration in which the same data signal is supplied via different data lines 114 has a considerable number of redundant portions. Therefore, a third embodiment in which such a redundant part is eliminated will be described.
[0050]
FIG. 10 is a block diagram showing the configuration of the data line driving circuit 140 in this electro-optical device. The data line driving circuit 140 shown in this figure is common to the above-described second embodiment (see FIG. 9) except that there is no data line 114 to which a common data signal is supplied. On the other hand, the sub-pixels in the electro-optical device according to the present embodiment are arranged as shown in FIG.
That is, in this embodiment, two B subpixels belonging to two pixels adjacent to each other in the horizontal scanning direction are combined into one, and similarly, two Rs belonging to two pixels adjacent to each other in the horizontal scanning direction are combined. The sub-pixels are combined into one, and the data line 114 to which a common data signal is supplied to the two sub-pixels is omitted.
[0051]
Specifically, if j is an odd number, the pixel in the jth column and the B subpixel belonging to the pixel in the (j + 1) th column are combined into one, and the pixel in the subsequent (j + 1) th column , The R sub-pixels belonging to the pixels in the (j + 2) column are grouped into one (stripe arrangement). Further, the number of sub-pixels combined into one for both R and B is approximately twice the area of each G sub-pixel.
According to such an electro-optical device, as in the second embodiment, the configuration can be simplified and the power consumption can be reduced, and the number of outputs of the conversion circuit 1440 and the total number of sub-pixels in the display area can be reduced. Will be reduced. For this reason, since the area occupied by the gap between the sub-pixels decreases, the ratio of the area occupied by the sub-pixels increases in the display region, and as a result, the aperture ratio improves. Therefore, in the present embodiment, it is possible to achieve a bright display with a high contrast ratio.
[0052]
In the third embodiment, in addition to the arrangement shown in FIG. 11A, the arrangement shown in FIG. 11B, FIG. 11C, FIG. It is. That is, the arrangement shown in FIG. 11B is obtained by replacing the R and B sub-pixels in FIG. 11A for each row, and the arrangement shown in FIG. The arrangement in FIG. 11B is shifted by 1/3 pixel (1 sub-pixel) while maintaining the linearity of the line, and the arrangement shown in FIG. The pixel arrangement is shifted by 0.5 pixels (delta arrangement).
In the third embodiment, as in the modification in the first embodiment, the gradation data DR, DG, and DB may be input via dedicated signal lines, and the sampling timings of R and B are switched. May be.
[0053]
<Fourth embodiment>
In the first, second, and third embodiments described above, in two pixels adjacent to each other in the horizontal scanning direction, R sub-pixels have the same gradation, and similarly, B sub-pixels have the same gradation. However, the adjacent direction between two pixels is not limited to the horizontal scanning direction, and may be the vertical scanning direction.
Therefore, a fourth embodiment will be described in which R and B subpixels belonging to two pixels adjacent to each other in the vertical scanning direction instead of the horizontal scanning direction have the same gradation.
[0054]
FIG. 12 is a block diagram showing the configuration of the data line driving circuit 140 in this electro-optical device. In this figure, the row selection signal O / E becomes H level during the horizontal scanning period in which the gradation data DR and DG corresponding to the odd-numbered sub-pixels are supplied, while corresponding to the even-numbered sub-pixels. It becomes L level during the horizontal scanning period in which the gradation data DG and DB are supplied, and the selection of the switch 1450 is controlled. The switch 1450 is provided corresponding to the pixel column. When the row selection signal O / E is at the H level, the switch 1450 supplies the sampling control signal to the register 1420 corresponding to the R sub-pixel, while the row selection signal When O / E is at the L level, the sampling control signal is supplied to the register 1420 corresponding to the B sub-pixel.
[0055]
As described above, in the data line driving circuit 140 that supplies data signals line-sequentially, the timing at which the gradation data is sampled in the register 1420 is that the data signal according to the sampled gradation data is actually applied to the data line 114. There is a relationship that precedes the supply timing by one horizontal scanning period. For this reason, the horizontal scanning period in which the gradation data DR and DG corresponding to the sub-pixels in the odd-numbered rows is supplied refers to a period in which the scanning line 112 one row before the odd-numbered rows is selected. The horizontal scanning period in which the gradation data DG, DB corresponding to the eye sub-pixel is supplied refers to a period in which the scanning line 112 one row before the even-numbered row is selected.
In other words, in the horizontal scanning period in which the even-numbered scanning line 112 is selected, the gradation data DR and DG corresponding to the odd-numbered subpixels one row before the even-numbered row are supplied. On the other hand, in the horizontal scanning period in which the odd-numbered scanning lines 112 are selected, the gradation data DG and DB corresponding to the even-numbered subpixels one row before the odd-numbered rows are supplied. It will be.
[0056]
In such a configuration, in the horizontal scanning period in which the gradation data DR and DG corresponding to the odd-numbered sub-pixels are supplied, each of the switches 1450 selects the register 1420 corresponding to the R sub-pixel, Each selected sampling control signal is supplied. Therefore, in the horizontal scanning period, the gradation data DR supplied to the signal line 144 is sampled at the rising edge of the sampling control signal by the register 1420 corresponding to the R sub-pixel.
Note that in the horizontal scanning period, the register 1420 corresponding to the B sub-pixel latches and outputs the gradation data DB sampled in the immediately preceding horizontal scanning period.
[0057]
Subsequently, in the horizontal scanning period in which the gradation data DG and DB corresponding to the even-numbered subpixels are supplied, each of the switches 1450 selects the register 1420 corresponding to the B subpixel and selects the selected sampling. Supply control signals respectively. Therefore, in the horizontal scanning period, the gradation data DB supplied to the signal line 144 is sampled at the rising edge of the sampling control signal by the register 1420 corresponding to the B sub-pixel.
Note that in the horizontal scanning period, the register 1420 corresponding to the R sub-pixel subsequently latches and outputs the gradation data DR sampled in the immediately preceding horizontal scanning period.
[0058]
The gradation data DG is sampled at the rising edge of the sampling control signal by the register 1420 corresponding to the G sub-pixel regardless of the odd-numbered row and the even-numbered row.
[0059]
Therefore, according to this configuration, in the horizontal scanning period in which the odd-numbered scanning lines 112 are generally selected, the data signals Rj, Gj, Bj corresponding to the pixels in the j-th column are as follows. Become. That is, the data signals Rj and Gj are the gradation data DR and DG sampled in the immediately preceding horizontal scanning period, and the gradation data DR and DG of the R and G sub-pixels belonging to the pixels in the odd row j column. Are converted by the conversion circuit 1440, respectively. On the other hand, the data signal Bj continuously converts the gradation data DB of the B sub-pixel belonging to the pixel in the even-numbered row j column one row before the odd-numbered row from the previous horizontal scanning period to the horizontal scanning period, 1440 is converted.
In the subsequent horizontal scanning period in which the even-numbered scanning line 112 is selected, the data signals Gj and Bj corresponding to the pixels in the j-th column are the gradation data DG, DB, which is obtained by converting the gradation data DG and DB of the G and B sub-pixels belonging to the pixel of the even row j column by the conversion circuit 1440, respectively, while the data signal Rj is 1 from the even row. The gradation data DR of the R sub-pixel belonging to the pixel in the odd-numbered row j column before the row is converted by the conversion circuit 1440 continuously from the previous horizontal scanning period to the horizontal scanning period.
[0060]
In this configuration, there is no data signal corresponding to the B sub-pixel in the first row scanning line 112. However, the 0th row scanning line is virtually provided, and The gray scale data DB shared by the 0th and 1st rows may be sampled before the horizontal scanning period during which the scanning line is selected.
[0061]
As described above, according to the electro-optical device according to the fourth embodiment, the G sub-pixel has the gradation specified individually for each pixel, but in two pixels adjacent in the vertical scanning direction, the R sub-pixel The sub-pixels have the same gradation, and similarly, the B sub-pixels also have the same gradation.
For this reason, in the present embodiment, the signal line 144 is supplied with the gradation data DR of the sub-pixel corresponding to the row one row before the even-numbered row during the period when the even-numbered scanning line 112 is selected. On the other hand, in the period in which the subsequent odd-numbered scanning lines 112 are selected, the gradation data DB of the sub-pixels corresponding to the row preceding the odd-numbered row is supplied.
Therefore, the number of lines required for the signal lines 142 and 144 is only 12 according to the present embodiment, so that the power wasted due to the parasitic capacitance of the signal lines 142 and 144 is suppressed while suppressing the deterioration in display quality. Can be eliminated.
[0062]
In the fourth embodiment, the selection of the switch 1450 may be interchanged, and the R and B sampling timings may be interchanged. In the fourth embodiment, R subpixels located in the same column in the odd-numbered row and the following even-numbered row, and B subpixels located in the same column in the even-numbered row and the following odd-numbered row, Each may be combined into one as described in the third embodiment.
[0063]
<Fifth Embodiment>
In the first, second, third, and fourth embodiments described above, the R and B sub-pixels are shared by two adjacent pixels, so that there is a large color difference or gradation change between the pixels. In some cases, bleeding may occur.
Therefore, in such a case, the fifth embodiment in which the occurrence of bleeding is prevented by supplying individual gradation data without sharing the R and B sub-pixels in two adjacent pixels. explain.
[0064]
FIG. 13 is a block diagram illustrating a configuration of the data line driving circuit 140 in the electro-optical device according to the fifth embodiment. In this figure, a mode selection signal A / B is a signal for defining either the first mode or the second mode in the present embodiment.
Specifically, as shown in FIG. 14, the mode selection signal A / B is a first signal that shares R and B sub-pixels in two adjacent pixels in the horizontal scanning direction as in the first embodiment. If the mode is the L level, the signal is at the H level in the second mode in which the original gradation data changes more than a threshold value, as in the case of a large color difference or gradation change. is there.
Here, if the mode selection signal A / B is L level, the gradation data DG is supplied in 6 bits for each pixel, and the gradation data DR and DB are alternately supplied in 6 bits for every other pixel. The On the other hand, if the mode selection signal A / B is at the H level, each of the gradation data DR, DG, and DB is cut off the lower 2 bits out of the original 6 bits and only the upper 4 bits for each pixel. To be supplied.
[0065]
In addition, the switch SWr is generally connected to the register 1420 corresponding to the data line 114 to which the data signal Rj is supplied in the even number j, and if the mode selection signal A / B is at the L level, one column before the column. On the other hand, if the mode selection signal A / B is H level, the sampling control signal Xsj corresponding to the column is supplied.
Further, the switch SWb is connected to the register 1420 corresponding to the data line 114 to which the data signal B (j + 1) is supplied at the next odd number (j + 1) after the even number j, and the mode selection signal A / B is at the L level. While the sampling control signal Xsj corresponding to the previous column is supplied, if the mode selection signal A / B is at the H level, the sampling control signal Xs (j + 1) corresponding to the column is supplied. . However, as an exception, the switch 14b is not provided in the register 1420 corresponding to the data line 114 to which the data signal B1 is supplied, and the pulse signal DX is supplied as a substitute for the sampling control signal.
[0066]
Next, the switching circuit 1460 supplies the gradation data DR, DG, DB supplied to the signal lines BA, BB to the signal lines 142, 144, 146 according to the level of the mode selection signal A / B. In detail, the configuration is as shown in FIG.
Each of the eight switches in this figure selects the input terminal a if the mode selection signal A / B is L level, and selects the input terminal b if the mode selection signal A / B is H level. To do.
[0067]
The signal line BA on the input side consists of six bus lines BA5 (highest) to BA0 (lowest), and similarly, the signal line BB is bus lines BB5 (highest) to BB0 (lowest). It consists of six. On the other hand, the signal line 146 on the output side to the register 1420 is composed of six bus lines R5 (highest) to R0 (lowest), and similarly, the signal line 142 is connected to the bus lines G5 (highest) to G0. Similarly, the signal line 144 is composed of six bus lines B5 (most significant) to B0 (lowest).
Here, in the present embodiment, in the first mode in which the mode selection signal A / B is at the L level, the gradation data DG is supplied in 6 bits for each pixel via the bus lines BB0 to BB5. The gradation data DR and DB are alternately supplied in 6 bits every other pixel via the bus lines BA5 to BA0.
On the other hand, in the second mode in which the mode selection signal A / B is at the H level, the gradation data DR is 4 bits via the bus lines BA5 to BA2, and the gradation data DG is the bus lines BB5 to BB2. Further, the gradation data DB is supplied for each pixel in 4 bits via the bus lines BB1, BA1, BB0, and BA0.
[0068]
Therefore, in the switching circuit 1460, in the first mode, the 6-bit gradation data DG is supplied for each pixel via the bus lines G5 to G0 constituting the signal line 142, and 6 Bit gradation data DR (DB) is supplied every other pixel via bus lines R5 to R0 (B5 to B0) constituting the signal line 144 (146).
On the other hand, in the second mode, the gradation data DR is supplied for each pixel via the bus lines R5 to R2 in the signal line 146, and the gradation data DG is included in the signal line 142. The grayscale data DB is supplied for each pixel via the bus lines B5 to B2 in the signal line 144. Further, the gradation data DB is supplied for each pixel via the bus lines G5 to G2.
In the second mode, the bus lines G1 and G0 of the signal line 142, the bus lines B1 and B0 of the signal line 144, and the bus lines R1 and R0 of the signal line 146 are respectively switched. Therefore, the lower 2 bits are discarded.
[0069]
Returning to FIG. 13, in the present embodiment, the pulse signal DX is the same as in the first embodiment described above in that it rises at the beginning of the horizontal scanning period, but thereafter, until the latch pulse LP rises. It is different from the first embodiment in that it is held at the H level.
Further, the shift register 1470 is similar to the shift register 1410 according to the first embodiment described above in that the shift register 1470 sequentially shifts at every rising edge of the clock signal XsCK. However, in the configuration that is reset by the latch pulse LP, the shift register 1470 1410.
[0070]
Next, the operation of the electro-optical device according to this embodiment will be described. FIG. 16 is a timing chart for explaining the operation of the electro-optical device. In this figure, if the mode selection signal A / B is at the L level, the data Da indicates 6-bit gradation data supplied through the bus lines BA5 to BA0 of the signal line BA. If the selection signal A / B is at the H level, it indicates 4-bit gradation data supplied via the bus lines BA5 to BA2 of the signal line BA. Similarly, if the mode selection signal A / B is at the L level, the data Db indicates 6-bit gradation data supplied via the bus lines BB5 to BB0 of the signal line BB. If the signal A / B is at the H level, it indicates 4-bit gradation data supplied via the bus lines BB5 to BB2 in the signal line BB.
Further, the data Dc indicates 4-bit gradation data supplied via the bus lines BA1 (most significant), BA0, BB1, and BB0 (lowest) only when the mode selection signal A / B is H level. ing.
[0071]
In this embodiment, in the first mode in which the mode selection signal A / B is at the L level, the switch SWr generally corresponds to the data line 114 to which the data signal Rj is supplied in the even number j. The sampling control signal Xs (j−1) corresponding to the previous column is supplied to the register 1420, and the switch SWb receives the data signal B (j + 1) at the odd number (j + 1) next to the even number j. Is supplied to the register 1420 corresponding to the data line 114 supplied with the sampling control signal Xsj corresponding to one column before the column.
Therefore, in this embodiment, in the first mode, 6-bit gradation data DR, DG, and DB are respectively stored in the register 1420 at the same timing as the modified configuration of the first embodiment (see FIG. 7). It will be sampled. That is, the gradation data DG is sampled individually for each pixel, and the gradation data DR and DB are sampled in common by two pixels adjacent in the horizontal direction.
[0072]
On the other hand, in this embodiment, in the second mode in which the mode selection signal A / B is at the H level, the switch SWr is generally connected to the data line to which the data signal Rj is supplied when j is an even number. The sampling control signal Xsj corresponding to the column is supplied to the register 1420 corresponding to 114, and the switch SWb is a data line to which the data signal B (j + 1) is supplied in the odd number (j + 1) next to the even number j. The sampling control signal Xs (j + 1) corresponding to the column is supplied to the register 1420 corresponding to 114.
Therefore, in the present embodiment, if the mode selection signal A / B is the second mode in which the H level is set, the 4-bit gradation data DR, DG, and DB are individually sampled for each pixel. Become.
[0073]
Here, the gradation data DR, DG, and DB supplied in the period of the second mode are obtained by rounding down the lower 2 bits of the original 6 bits. There is a possibility that a peculiar pattern appears in the display portion where the gradual change occurs. However, in the present embodiment, the transition to the second mode is when there is a large color difference or gradation change, and not when displaying a portion where gradation occurs gently. For this reason, in the present embodiment, the occurrence of patterns in the second mode is considered to be less problematic.
[0074]
In the fifth embodiment, when a photographic image such as a natural image is displayed, if the mode selection signal A / B is set to the L level to be in the first mode, a person will have less influence when determining the brightness. The gradation data DR and DB supplied to the R and B subpixels that are not provided are shared by two adjacent pixels. For this reason, it is possible to reduce power consumption while suppressing deterioration of display quality.
On the other hand, in the fifth embodiment, when a character such as a character or a line drawing is displayed, if the mode selection signal A / B is set to the H level and the second mode is set, the occurrence of bleeding is suppressed and high-quality display is performed. It becomes possible.
For this reason, in the fifth embodiment, by selecting the first or second mode according to the display content, it is possible to achieve both low power consumption and prevention of deterioration in display quality. Further, the fifth embodiment has a complicated configuration because the switching circuit 1460 and the wiring for supplying the mode selection signal A / B are substantially added as compared with the fourth embodiment. Prevention and lower power consumption associated therewith can be achieved.
[0075]
Note that FIG. 16 is a timing at which gradation data DR, DG, and DB corresponding to the pixels in the third column are supplied, assuming that the gradation of only the pixels in the third column changes by more than a threshold value. In FIG. 2, the mode selection signal A / B is in the H level, but the present embodiment is not limited to this. That is, the mode selection signal A / B may be at the H level over a plurality of columns or rows, and may be at the H level over the entire display region.
[0076]
Further, the mode selection signal A / B may be set to the H level only when scanning a specific area. For example, when a screen as shown in FIG. 17 is displayed, the mode selection signal A / B is set to the H level only during the period of horizontal scanning of the area for displaying characters, numbers, line drawings and the like. In other periods, if the mode selection signal A / B is set to the L level, optimum driving according to the display content is executed.
[0077]
<Summary of electro-optical device>
In the first to fifth embodiments described above, since the sub-pixel 120 is switched by the TFT 116 as shown in FIG. 2A, the conversion circuit 1440 converts the latched gradation data into The analog signal having the polarity indicated by the signal AK is converted into an analog signal and supplied to the data line 114 as a data signal. However, the present invention is not limited to this, and various configurations of the sub-pixel 120 can be employed. For example, in addition to the TFT 116, a field effect transistor formed on a semiconductor substrate may be used.
[0078]
In addition to the three-terminal element, a two-terminal element such as a TFD (Thin Film Diode) 117 can also be used as shown in FIG. Here, in FIG. 2B, at the intersection of the scanning line 112 and the data line 114, one end of the TFT 117 is connected to the scanning line 112, and the other end is connected to the pixel electrode 118. Yes. On the other hand, the data line 114 is a striped electrode facing the pixel electrode 118.
In this configuration, when a scanning line 112 in one row is selected, if a scanning signal that turns on the TFD 117 is supplied to the scanning line 112 regardless of the data signal applied to the data line 114, the TFD 117 is forcibly set. Turns on. For this reason, the liquid crystal capacitor sandwiching the liquid crystal 105 between the pixel electrode 118 and the data line 114 has a charge corresponding to the voltage difference applied to the scanning line 112 and the data line 114 via the TFD 117 that is turned on. Will be accumulated.
Therefore, when the sub-pixel 120 is switched by the TFD 117, the conversion circuit 1440 has a polarity that is opposite to that of the scanning signal supplied to the selected scanning line 112 and corresponds to the latched gradation data. What is necessary is just to make it the structure which converts into the signal which has a width | variety, and supplies this as a data signal.
In FIG. 2B, one end of the TFD 117 is connected to the scanning line 112, but one end of the TFD 117 is connected to the data line 114, and the scanning line 112 may be a striped electrode.
[0079]
Furthermore, the present invention is not limited to the active matrix system, and can also be applied to a passive matrix system as shown in FIG.
Here, in FIG. 2C, the scanning line 112 is formed as a striped common electrode extending in the X direction, and the data line 114 is a striped segment extending in the Y direction. It is formed as an electrode. The liquid crystal 105 is sandwiched at a portion where the two intersect, and a liquid crystal capacitance is formed.
The conversion circuit 1440 applied to such a passive matrix type has a polarity opposite to that of the scanning signal supplied to the selected scanning line 112 in the same manner as the TFD 117, and corresponds to the latched gradation data. The signal may be converted into a signal having a pulse width and supplied as a data signal.
[0080]
On the other hand, the above-described data line driving circuit 140 has been described by taking line sequential driving as an example in which all data signals are supplied simultaneously at the rising edge of the latch pulse LP. However, the sampled gradation data is immediately converted into a data signal. Thus, dot-sequential driving may be performed. Note that the latch circuit 1430 is unnecessary in this dot sequential driving.
[0081]
In addition, the electro-optical device described above has been described by taking the transmissive type of the liquid crystal display device as an example, but it can be applied to any of a reflective type and a transflective type in addition to the transmissive type. Furthermore, the electro-optical device can be applied to various devices such as an organic EL device, a fluorescent display tube, a plasma display panel, and a digital mirror device.
[0082]
<Electronic equipment>
Next, some electronic apparatuses using the electro-optical device according to the above-described embodiment will be described.
[0083]
<Part 1: Mobile personal computer>
First, an example in which the above-described electro-optical device is applied to a display unit of a mobile personal computer will be described. FIG. 18 is a perspective view showing the configuration of this personal computer. In the figure, a computer 2100 includes a main body 2104 having a keyboard 2102 and an electro-optical device 100 used as a display unit. In the case where a liquid crystal display device is used as the electro-optical device 100, a backlight is provided on the back surface in order to ensure visibility in a dark place.
[0084]
<Part 2: Digital still camera>
Next, a digital still camera using the above-described electro-optical device as a finder will be described. FIG. 19 is a perspective view showing the back of the digital still camera. A normal silver salt camera sensitizes a film with a light image of a subject, whereas a digital still camera 2200 generates an image signal by photoelectrically converting a light image of a subject with an image sensor such as a CCD (Charge Coupled Device). To do.
[0085]
Here, the electro-optical device 100 described above is provided on the back surface of the case 2202 in the digital still camera 2200, and is configured to perform display based on an imaging signal from the CCD. Therefore, the electro-optical device 100 functions as a finder that displays a subject.
Also in this digital still camera 2200, when a liquid crystal display device is used as the electro-optical device 100, a backlight is provided on the back surface (not shown) to ensure visibility in a dark place.
[0086]
A light receiving unit 2204 including an optical lens and a CCD is provided on the front side (the back side in FIG. 19) of the case 2202. Here, when the photographer confirms the subject image displayed on the electro-optical device 100 and presses the shutter button 2206, the CCD image pickup signal at that time is transferred and stored in the memory of the circuit board 2208.
In the digital still camera 2200, a video signal output terminal 2212 and an input / output terminal 2214 for data communication are provided on the side surface of the case 2202 for external display.
[0087]
<Part 3: Mobile phone>
Further, an example in which the above-described electro-optical device is applied to a display unit of a mobile phone will be described. FIG. 20 is a perspective view showing the configuration of this mobile phone. In the figure, a mobile phone 2300 includes the electro-optical device 100 described above, in addition to a plurality of operation buttons 2302, as well as an earpiece 2304 and a mouthpiece 2306. When a liquid crystal display device is used as the electro-optical device 100, a backlight is used for a transmissive type or a semi-transmissive / semi-reflective type, and a front light is used for a reflective type in order to ensure visibility in a dark place. (Both not shown) are provided.
[0088]
<Summary of electronic devices>
In addition to the electronic devices described with reference to FIGS. 18, 19 and 20, the electronic devices include a liquid crystal television, a viewfinder type / direct monitor type video tape recorder, a car navigation device, a pager, an electronic notebook, Examples include calculators, word processors, workstations, videophones, POS terminals, devices with touch panels, and the like. Needless to say, the electro-optical device according to the embodiment, application, or modification can be applied to these various electronic devices.
[0089]
【The invention's effect】
As described above, according to the present invention, in the electro-optical device, it is possible to simplify the configuration, reduce the power consumption, and the like while suppressing deterioration in display quality.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration of an electro-optical device according to a first embodiment of the invention.
FIGS. 2A, 2B, and 2C are diagrams each showing an equivalent circuit of a pixel in the electro-optical device. FIGS.
FIG. 3 is a block diagram showing a configuration of a data line driving circuit in the electro-optical device.
FIG. 4 is a timing chart for explaining R, G, and B gradation data supplied to the electro-optical device.
FIG. 5 is a timing chart for explaining an operation in the electro-optical device.
FIG. 6 is a timing chart for explaining an operation in the electro-optical device.
FIG. 7 is a block diagram showing a modified configuration of the data line driving circuit of the electro-optical device.
FIG. 8 is a timing chart for explaining an operation in the electro-optical device.
FIG. 9 is a block diagram illustrating a configuration of a data line driving circuit of an electro-optical device according to a second embodiment of the invention.
FIG. 10 is a block diagram illustrating a configuration of a data line driving circuit of an electro-optical device according to a third embodiment of the invention.
FIGS. 11A, 11B, 11C, and 11D are diagrams illustrating arrangements of sub-pixels applicable to the electro-optical device. FIGS.
FIG. 12 is a block diagram illustrating a configuration of a data line driving circuit of an electro-optical device according to a fourth embodiment of the invention.
FIG. 13 is a block diagram illustrating a configuration of a data line driving circuit of an electro-optical device according to a fifth embodiment of the invention.
FIG. 14 is a timing chart for explaining R, G, and B gradation data supplied to the electro-optical device.
FIG. 15 is a diagram showing a configuration of a switching circuit in the data line driving circuit;
FIG. 16 is a timing chart for explaining an operation in the electro-optical device.
FIG. 17 is a plan view showing a display example in the electro-optical device.
FIG. 18 is a perspective view illustrating a configuration of a personal computer as an example of an electronic apparatus to which the electro-optical device according to the embodiment is applied.
FIG. 19 is a perspective view illustrating a rear configuration of a digital still camera as an example of an electronic apparatus to which the electro-optical device according to the embodiment is applied.
FIG. 20 is a perspective view illustrating a configuration of a mobile phone as an example of an electronic apparatus to which the electro-optical device according to the embodiment is applied.
[Explanation of symbols]
100: Electro-optical device
105 ... Liquid crystal
108 ... Counter electrode
112 ... Scanning line
114 ... data line
116 ... TFT
118: Pixel electrode
120: Sub-pixel
130: Scanning line driving circuit
140 Data line driving circuit
142, 144, 146 ... signal lines
1410: Shift register
1420: Register
1430 ... Latch circuit
1440: Conversion circuit
1450 ... switch
1460: switching circuit

Claims (10)

The sub-pixels provided at the intersections of the scanning lines and the data lines and having gradations corresponding to the data signals supplied to the data lines when the scanning lines are selected are red (R), green ( G), an electro-optical device that corresponds to each of blue (B) and performs color display of one pixel by three sub-pixels of RGB,
A data signal based on the R gradation data is commonly supplied to the R subpixels belonging to each of the two pixels adjacent to each other in either the horizontal scanning direction or the vertical scanning direction, and also to the two adjacent pixels. A data signal based on the B gradation data is supplied to each of the B sub-pixels belonging to the B sub-pixel,
For the G sub-pixel, a data signal based on the G gradation data is supplied for each pixel ,
If the supplied gradation data is m bits for each of RGB,
If the difference between RGB gradation data in two adjacent pixels is equal to or greater than a threshold value, data based on the R or B gradation data for each of the R or B subpixels belonging to the two pixels. Without supplying a common signal,
For each of the RGB sub-pixels, a data signal based on the upper n (n is an integer satisfying 3n ≦ 2m) bit data among m-bit gradation data, respectively. An electro-optical device characterized by being supplied . The data signal supplied in common to the sub-pixels belonging to each of the two adjacent pixels is based on one of the gradation data corresponding to each of the sub-pixels belonging to the two pixels or an average value thereof. The electro-optical device according to claim 1. The R sub-pixels belonging to each of the two adjacent pixels are combined into one, and the B sub-pixels belonging to each of the two adjacent pixels are combined into one. 2. The electro-optical device according to 1. Sub pixels summary was R, and the area of the sub-pixel summary was B are as defined in claim 3, characterized in that each substantially twice the area of the sub-pixel of the G Electro-optic device. An electronic apparatus comprising the electro-optical device according to any one of claims 1 to 4. The sub-pixels provided at the intersections of the scanning lines and the data lines correspond to red (R), green (G), and blue (B), respectively, and color display of one pixel is performed by three RGB sub-pixels. Used in electro-optic devices to perform,
A driving circuit for supplying a data signal to the sub-pixel corresponding to the selected scanning line via the data line;
A data signal based on R gradation data is commonly supplied to each of R subpixels belonging to two adjacent pixels in either one of the horizontal scanning direction and the vertical scanning direction, and also belongs to the two pixels. While supplying a data signal based on the B gradation data to each of the B sub-pixels in common,
For the G sub-pixel, a data signal based on the G gradation data is supplied for each pixel ,
Having a first mode and a second mode;
In the first mode, G gradation data is supplied and R gradation data and B gradation data are alternately supplied for each pixel, while in the second mode, RGB gradation data is supplied. A signal line in which gradation data is supplied with a reduced number of bits in the first mode;
A conversion circuit that is provided for each data line, converts the supplied gradation data into a data signal, and supplies the data signal to the corresponding data line;
In the first mode, in a period in which R gradation data is supplied to the signal line,
The G gradation data supplied to the signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. A common supply to the conversion circuit corresponding to each of the R data line belonging to the pixel column and the R data line belonging to the pixel column adjacent to the pixel column ;
In a period in which B gradation data is supplied to the signal line,
The G gradation data supplied to the signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to the other pixel column, and the B gradation data is sampled. While commonly supplying to the conversion circuit corresponding to each of the B data line belonging to the pixel column and the B data line belonging to the pixel column adjacent to the pixel column,
In the second mode, the R or B sub-pixels belonging to the two adjacent pixels are not commonly supplied with data signals based on the R or B gradation data, A mechanism for supplying RGB gradation data supplied to a signal line to a conversion circuit corresponding to each of the data lines belonging to a certain pixel column;
A drive circuit for an electro-optical device, comprising: A G signal line to which G gradation data is supplied;
An RB signal line in which R gradation data and B gradation data are alternately supplied to each pixel;
A conversion circuit that is provided for each data line, converts the supplied gradation data into a data signal, and supplies the data signal to the corresponding data line;
During a period in which R gradation data is supplied to the RB signal line,
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. While commonly supplying to the conversion circuit corresponding to each of the R data line belonging to the pixel column and the R data line belonging to the pixel column adjacent to the pixel column,
During the period when the B gradation data is supplied to the RB signal line,
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to another pixel column, and the B gradation data is sampled. And a register commonly supplied to a conversion circuit corresponding to each of the B data line belonging to the pixel column and the B data line belonging to the pixel column adjacent to the pixel column. 7. A drive circuit for the electro-optical device according to 6 . An R signal line to which R gradation data is supplied;
A G signal line to which G gradation data is supplied;
A B signal line to which B gradation data is supplied;
A conversion circuit that is provided for each data line, converts the supplied gradation data into a data signal, and supplies the data signal to the corresponding data line;
During a period in which R gradation data is supplied to the R signal line,
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. While commonly supplying to the conversion circuit corresponding to each of the R data line belonging to the pixel column and the R data line belonging to the pixel column adjacent to the pixel column,
Corresponding to the G data line belonging to another pixel column by sampling the G gradation data supplied to the G signal line during the period when the B gradation data is supplied to the B signal line The B grayscale data is sampled and corresponds to each of the B data line belonging to the pixel column and the B data line belonging to the pixel column adjacent to the pixel column. The drive circuit for the electro-optical device according to claim 6 , further comprising: a register that is commonly supplied to the conversion circuit. A G signal line to which G gradation data is supplied;
An RB signal line in which R gradation data and B gradation data are alternately supplied for each pixel;
G is provided for each data line, while R or B is provided for every two data lines belonging to adjacent pixel columns, and the supplied grayscale data is converted into a data signal, and data A conversion circuit for converting to a line;
During a period in which R gradation data is supplied to the RB signal line,
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to a certain pixel column, and the R gradation data is sampled. While supplying to the conversion circuit corresponding to the R data line belonging to the pixel column and the R data line paired therewith,
During the period when the B gradation data is supplied to the RB signal line,
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to another pixel column, and the B gradation data is sampled. The electro-optical device according to claim 6 , further comprising: a register that supplies a conversion circuit corresponding to the B data line belonging to the pixel column and the B data line paired with the B data line. Drive circuit. A G signal line to which G gradation data is supplied;
In the horizontal scanning period in which one of the odd-numbered or even-numbered scanning lines is selected, R grayscale data is supplied, while in the horizontal scanning period in which one of the other scanning lines is selected, B An RB signal line to which the grayscale data is supplied;
A conversion circuit that is provided for each data line, converts the supplied gradation data into a data signal, and supplies the data signal to the corresponding data line;
The gray scale data supplied to the G signal line is sampled, and the conversion circuit corresponding to the G data line belonging to a certain pixel column is subjected to a horizontal scanning period in which the one scanning line is selected. While supplying
R gradation data supplied to the RB signal line is sampled, held for a period until selection of the next scanning line is completed, and supplied to the conversion circuit corresponding to the R data line belonging to the pixel column. While
The G gradation data supplied to the G signal line is sampled and supplied to the conversion circuit corresponding to the G data line belonging to the pixel column in the horizontal scanning period in which the other scanning line is selected. With
The B grayscale data supplied to the RB signal line is sampled, held for a period until the selection of the next scanning line is completed, and supplied to the conversion circuit corresponding to the B data line belonging to the pixel column. The drive circuit for the electro-optical device according to claim 6 , further comprising:

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