JP7259718B2 - ELECTRO-OPTICAL DEVICE, METHOD FOR DRIVING ELECTRO-OPTICAL DEVICE, AND ELECTRONIC DEVICE - Google Patents

Description

The present invention relates to an electro-optical device, an electro-optical device driving method, and an electronic apparatus.

An electro-optical device that displays an image using a liquid crystal element supplies a video voltage based on an image signal that specifies the gradation of each pixel to each pixel through a data line, thereby controlling the transmission of the liquid crystal of each pixel. Controls rate to transmittance based on video voltage. As a result, the gradation of each pixel is set to the gradation designated by the image signal. Generally, each pixel has a storage capacitor connected in parallel with the liquid crystal element. One end of the storage capacitor is connected to the pixel electrode of the liquid crystal element, and the other end is connected to the common electrode of the liquid crystal element via a capacitance line.

When the video voltage supply to each pixel is insufficient, such as when the time to supply the video voltage to each pixel is insufficient, each pixel cannot accurately display the gradation specified by the image signal. Sometimes you can't. For this reason, in the conventional electro-optical device, for example, precharging is performed to precharge the data line to a predetermined voltage level, so as to cope with insufficient writing of the video voltage to each pixel. For example, in Patent Document 1, a large number of data lines are divided into X blocks each containing a predetermined number of data lines, and at the same time an image signal is applied to the data lines included in the n-th block, A liquid crystal display device has been proposed in which a precharge voltage is applied to a data line connected to the display.

JP-A-2000-89194

However, when the video voltage or the precharge voltage is supplied to the data line, the change in the voltage level of the data line is propagated to the capacitance line via the coupling capacitance between the data line and the capacitance line, generating noise in the capacitance line. The conventional electro-optical device has a problem of display unevenness due to the influence of noise generated in the capacitive line.

In one aspect of the electro-optical device of the present invention to solve the above problems, a plurality of scanning lines, k (k is an integer of 3 or more) signal lines, a reference line to which a reference potential is applied, the plurality of a pixel arranged corresponding to each intersection of the scanning line and the k signal lines, including a storage capacitor connected to the reference line, and holding a potential corresponding to an image signal in the storage capacitor; an image signal circuit for sequentially supplying image signals to the k signal lines during k supply periods based on k selection signals for sequentially selecting the k signal lines in a scanning period; a precharge circuit for supplying a precharge signal in a predetermined order to the signal lines among the k signal lines before the image signal circuit supplies the image signal in the scanning period; At least one of the first supply period and the last supply period of the k supply periods for sequentially supplying the image signal to each of the k signal lines is set to the first supply period of the k supply periods. a control circuit for controlling the k selection signals to be longer than a predetermined supply period excluding the supply period and the last supply period.

In one aspect of the method for driving an electro-optical device according to the present invention, a plurality of scanning lines, k (k is an integer equal to or greater than 3) signal lines, a reference line to which a reference potential is applied, and the plurality of a pixel arranged corresponding to each intersection of the scanning line and the k signal lines, including a holding capacitor connected to the reference line, and holding a potential corresponding to an image signal in the holding capacitor; and horizontal scanning. an image signal circuit that sequentially supplies image signals to the k signal lines in k supply periods based on k selection signals that sequentially select the k signal lines in the period; and a precharge circuit for supplying precharge signals in a predetermined order to the signal lines among the k signal lines before the image signal circuit supplies the image signals during the period. wherein, in the horizontal scanning period, at least one of the first supply period and the last supply period among the k supply periods for sequentially supplying the image signal to each of the k signal lines is selected from the The k selection signals are controlled to be longer than a predetermined supply period excluding the first supply period and the last supply period among the k supply periods.

1 is an explanatory diagram of an electro-optical device according to a first embodiment of the invention; FIG. 1 is a block diagram showing the configuration of an electro-optical device according to a first embodiment; FIG. 3 is a circuit diagram showing the configuration of a pixel; FIG. FIG. 4 is a diagram showing the relationship between the potential movement of a signal line and the potential movement of a capacitor line; It is a figure which shows the operation|movement timing of a 1st horizontal scanning period. FIG. 10 is a diagram showing operation timings in a second horizontal scanning period; It is a figure which shows the operation|movement timing of a 3rd horizontal scanning period. It is a figure which shows the operation|movement timing of a 4th horizontal scanning period. It is a figure which shows the operation|movement timing of a 5th horizontal scanning period. It is a figure which shows the operation|movement timing of a 6th horizontal scanning period. It is a figure which shows the operation|movement timing of a 7th horizontal scanning period. It is a figure which shows the operation|movement timing of an 8th horizontal scanning period. 4 is a flow chart showing an example of the operation of the electro-optical device according to the first embodiment; FIG. 10 is a diagram showing operation timings in the first horizontal scanning period in the second embodiment of the present invention; FIG. 11 is a diagram showing operation timings in a first horizontal scanning period in modification 1 of the first embodiment; FIG. 10 is a diagram showing operation timings in a second horizontal scanning period in modification 1; It is an explanatory view showing an example of electronic equipment. FIG. 11 is an explanatory diagram showing another example of an electronic device; FIG. 11 is an explanatory diagram showing another example of an electronic device;

<First embodiment>
A first embodiment of the present invention will be described with reference to FIGS. 1 to 13. FIG. FIG. 1 is an explanatory diagram of an electro-optical device 1 according to the first embodiment of the invention. 1 shows the configuration of a signal transmission system for the electro-optical device 1. As shown in FIG. The electro-optical device 1 includes an electro-optical panel 100 , a driving integrated circuit 200 such as a driver IC (Integrated Circuit), and a flexible circuit board 300 . The electro-optical panel 100 is connected to a flexible circuit board 300 on which the driving integrated circuit 200 is mounted. Also, the electro-optical panel 100 is connected to a host CPU (Central Processing Unit) device (not shown) via the flexible circuit board 300 and the driving integrated circuit 200 . The driving integrated circuit 200 is a device that receives an image signal and various control signals for driving control from the host CPU device via the flexible circuit board 300 and drives the electro-optical panel 100 via the flexible circuit board 300. be.

The electro-optical device 1 displays images using liquid crystal elements. For example, the electro-optical device 1 supplies a video voltage based on an image signal designating the gradation of each pixel to each pixel via a signal line, thereby adjusting the transmittance of the liquid crystal of each pixel based on the video voltage. Control the transmittance. As a result, the gradation of each pixel is set to the gradation designated by the image signal. Note that the electro-optical device 1 employs polarity reversal driving in which the polarity of the voltage applied to the liquid crystal element is reversed at regular intervals in order to prevent electrical deterioration of the electro-optical material. For example, the electro-optical device 1 inverts the level of the image signal supplied to the pixels via the signal line with respect to the center voltage of the image signal every vertical scanning period. Note that the period for inverting the polarity can be set arbitrarily, and may be, for example, a natural number multiple of the vertical scanning period. In this specification, when the voltage of the image signal is higher than a predetermined voltage such as the center voltage, the positive polarity is used, and when the voltage of the image signal is lower than the predetermined voltage, the negative polarity is used. .

FIG. 2 is a block diagram showing the configuration of the electro-optical device 1 according to the first embodiment. The electro-optical device 1 includes a plurality of scanning lines 120, a plurality of signal lines 122, a capacitor line 124 to which a reference potential is applied, a plurality of pixels PX, an image signal circuit 140, a precharge circuit 160, and scanning lines. It has a drive circuit 180 and a control circuit 280 . For example, among the blocks shown in FIG. 2, the control circuit 280, and the signal line drive circuit 240 and the precharge voltage control circuit 260, which will be described later, are included in the driving integrated circuit 200. FIG. 2, blocks other than the control circuit 280, the signal line drive circuit 240, and the precharge voltage control circuit 260 are included in the electro-optical panel 100. FIG. Capacitance line 124 is an example of a reference line.

The plurality of signal lines 122 are classified into a signal line group including k signal lines 122, for example. However, k is an integer of 3 or more. In the example shown in FIG. 2, k is 8 and the total number of signal lines 122 is 4,160. Therefore, the 4160 signal lines 122 are classified into 520 signal line groups including 8 signal lines 122 . Note that k is not limited to 8 as long as it is an integer of 3 or more. Also, the total number of signal lines 122 is not limited to the example shown in FIG. For example, the total number of signal lines 122 may be k. In this case, the number of signal line groups is one.

Each of the plurality of pixels PX is arranged corresponding to each intersection of the plurality of scanning lines 120 and the plurality of signal lines 122 . In the example shown in FIG. 2, the pixels PX are arranged in a matrix of 2160 rows×4160 columns. Note that the number of pixels PX is not limited to the example shown in FIG. Each pixel PX also has a storage capacitor Cst connected to the capacitor line 124, as shown in FIG. In FIG. 2, the row of pixels PX shown on the uppermost side of the figure is the first row, and the column of pixels PX shown on the leftmost side of the figure is the first column. Further, hereinafter, the scanning line 120 connected to the m-th row pixel PX is also referred to as the m-th row scanning line 120, and the signal line 122 connected to the n-th row pixel PX is also referred to as the n-th row pixel PX. Also referred to as signal line 122 . In the example shown in FIG. 2, m is an integer of 1 or more and 2160 or less, and n is an integer of 1 or more and 4160 or less.

A scanning signal G is supplied to the scanning line 120 , and an image signal S or a precharge signal PRC is supplied to the signal line 122 . The number at the end of the code of the scanning signal G corresponds to the row number. Also, the numbers at the end of the reference numerals of the image signal S, write switch SWv and precharge switch SWp, which will be described later, correspond to column numbers. A common voltage Vcom is supplied to the capacitance line 124 . The potential of the capacitance line 124 given by the common voltage Vcom, that is, the potential based on the common voltage Vcom is an example of the reference potential.

The image signal circuit 140 sequentially supplies the image signal S to each of the eight signal lines 122 included in each signal line group, that is, k signal lines 122 in the horizontal scanning period. The horizontal scanning period is a period for writing the video voltage based on the image signal S supplied to the signal line 122 of each column to the pixels PX of one row. A row to be written is selected by a scanning signal G supplied from the scanning line driving circuit 180 to the scanning line 120 .

The image signal circuit 140 includes a plurality of write selection circuits SUv provided corresponding to the plurality of signal line groups, and a signal line drive circuit 240 that outputs the image signal S to each write selection circuit SUv. For example, the write selection circuit SUv1 corresponds to a signal line group including eight signal lines 122 from the 1st to 8th columns, and selects the signal lines 122 to be supplied with the image signal S from the 1st to 8th columns. is selected from eight signal lines 122 up to . The write selection circuit SUv520 corresponds to a signal line group including eight signal lines 122 from the 4153rd column to the 4160th column, and selects the signal lines 122 to be supplied with the image signal S from the 4153rd column to the 4160th column. is selected from eight signal lines 122 up to . The image signal S is supplied to the signal line 122 selected by the write selection circuit SUv.

Each write selection circuit SUv has eight signal lines 122 included in the corresponding signal line group, that is, k write switches SWv respectively connected to the k signal lines 122 . The write switch SWv is, for example, an N-channel transistor composed of a TFT (thin film transistor) or the like, and switches between a conducting state and a non-conducting state according to the level of a write selection signal SEL received at a control terminal such as a gate. is set to either The write switch SWv may be a P-channel transistor or a switching element other than a TFT. The configuration of each write selection circuit SUv is the same except that the connection destinations of the terminals other than the control terminal of the write switch SWv are different for each write selection circuit SUv. Therefore, the configuration of the write selection circuit SUv1 will be mainly described below.

For example, the write selection circuit SUv1 has eight write switches SWv1-SWv8. One end of each of the write switches SWv1 to SWv8 is connected to each of the eight signal lines 122 from the 1st to 8th columns. The other ends of the write switches SWv1-SWv8 are connected to each other and receive the image signals S1-S8 from the signal line drive circuit 240 in order. Then, according to the control from the control circuit 280, which will be described later, the write switches SWv set to the conducting state among the write switches SWv1 to SWv8 are switched in order during one horizontal scanning period. As a result, the image signals S1 to S8 sequentially output from the signal line drive circuit 240 are supplied to the corresponding signal lines 122 in sequence.

For example, when the write selection signal SEL1 is set to a selection potential such as high level, the write switch SWv1 that receives the write selection signal SEL1 transitions to a conducting state. As a result, the image signal S1 is supplied from the signal line driving circuit 240 to the signal line 122 of the first column, and the signal line 122 of the first column is charged with the video voltage based on the image signal S1. The write selection signal SEL1 is also output to the write switch SWv of the same series as the write switch SWv1, for example, the write switch SWv4153 in each write selection circuit SUv other than the write selection circuit SUv1.

In the example shown in FIG. 2, the write switches SWv having the same remainder when the digit at the end of the code of the write switch SWv is divided by 8 are the write switches SWv of the same series, and the common write selection signal SEL is applied to the control terminal. to receive. For example, the write switch SWv1 is in the same series as the write switch SWv4153, and the write switch SWv8 is in the same series as the write switch SWv4160.

Hereinafter, the write switch SWv controlled by the write selection signal SELi is also referred to as the i-th series write switch SWv. Note that i is an integer of 1 or more and 8 or less, that is, an integer of 1 or more and k or less. The signal line 122 connected to the i-th series write switch SWv is also referred to as the i-th series signal line 122 . Therefore, the number at the end of the code of the write selection signal SEL corresponds to the series number of the signal line 122 to be controlled. Similarly, the number at the end of the code of the precharge selection signal PSEL, which will be described later, also corresponds to the series number of the signal line 122 to be controlled.

The signal line driving circuit 240 outputs the image signal S for eight pixels, that is, the image signal S for k pixels as a time-series serial signal to each write selection circuit SUv. For example, the signal line driving circuit 240 sequentially outputs the image signals S1-S8 to the write selection circuit SUv1 and sequentially outputs the image signals S4153-S4160 to the write selection circuit SUv520. The image signals S supplied to the signal lines 122 of the same series are output in parallel from the signal line drive circuit 240 to each write selection circuit SUv. That is, the signal line driving circuit 240 outputs the image signals S supplied to the signal lines 122 of the same series to each of the plurality of signal line groups in parallel.

During the horizontal scanning period, the precharge circuit 160 applies a predetermined precharge signal PRC to the signal line 122 among the k signal lines 122 included in each signal line group before the image signal circuit 140 supplies the image signal S. supplied in the order of As a result, the signal line 122 before the image signal S is supplied is charged to a predetermined precharge voltage based on the precharge signal PRC. That is, the precharge circuit 160 precharges the signal line 122 to a predetermined precharge voltage before the image signal S is supplied. The predetermined order is a pre-determined execution order of precharge, and may be the same order as the arrangement order of the signal lines 122 or may be a different order.

For example, the precharge circuit 160 includes a plurality of precharge selection circuits SUp provided corresponding to a plurality of signal line groups, and a precharge voltage control circuit 260 that outputs a precharge signal PRC to each precharge selection circuit SUp. have For example, the precharge selection circuit SUp1 corresponds to a signal line group including eight signal lines 122 from the 1st to 8th columns, and selects the signal lines 122 to which the precharge signal PRC is supplied from the 1st to 8th columns. Selection is made from eight signal lines 122 up to the column. The precharge selection circuit SUp520 corresponds to a signal line group including eight signal lines 122 from the 4153rd column to the 4160th column, and selects the signal lines 122 to be supplied with the precharge signal PRC from the 4153rd column to the 4160th column. Selection is made from eight signal lines 122 up to the column. A precharge signal PRC is supplied to the signal line 122 selected by the precharge selection circuit SUp.

Each precharge selection circuit SUp has eight signal lines 122 included in the corresponding signal line group, ie, k precharge switches SWp respectively connected to the k signal lines 122 . The precharge switch SWp is, for example, an N-channel transistor composed of a TFT or the like, and switches between a conducting state and a non-conducting state according to the level of a precharge selection signal PSEL received at a control terminal such as a gate. is set to The precharge switch SWp may be a P-channel transistor or a switching element other than a TFT. The configuration of each precharge selection circuit SUp is the same except that the signal line 122 connected to the precharge switch SWp is different for each precharge selection circuit SUp. Therefore, the configuration of the precharge selection circuit SUp1 will be mainly described below.

For example, the precharge selection circuit SUp1 has eight precharge switches SWp1-SWv8. One end of each of the precharge switches SWp1-SWp8 is connected to each of eight signal lines 122 from the 1st to 8th columns. The other ends of precharge switches SWp 1 -SWp 8 are connected to each other and receive precharge signal PRC from precharge voltage control circuit 260 . Then, the precharge switch SWp set to the conductive state is selected among the precharge switches SWp1 to SWp8 under the control of the control circuit 280, which will be described later. As a result, the precharge signal PRC output from the precharge voltage control circuit 260 is supplied to the signal line 122 connected to the conductive precharge switch SWp.

For example, when the precharge selection signal PSEL1 is set to a selection potential such as high level, the precharge switches SWp of the first series, such as the precharge switch SWp1 that receives the precharge selection signal PSEL1, transition to a conducting state. As a result, the precharge signal PRC is supplied from the precharge voltage control circuit 260 to the first series signal line 122, and the first series signal line 122 is charged to the precharge voltage based on the precharge signal PRC. The period during which the precharge selection signal PSEL is maintained at the selection potential is an example of the precharge period during which the precharge signal PRC is supplied to the signal line 122 .

The other end of each of the precharge switches SWp1-SWp8 is also connected to the other end of the precharge switch SWp of the precharge selection circuit SUp other than the precharge selection circuit SUp1. That is, the other ends of precharge switches SWp 1 -SWp 4160 are connected to each other and receive precharge signal PRC from precharge voltage control circuit 260 .

The precharge voltage control circuit 260 generates a precharge signal for supplying a precharge voltage based on the polarity of the image signal S to the signal line 122 based on a set value stored in an external set value storage means (not shown). PRC is output to a plurality of precharge switches SWp.

The scanning line driving circuit 180 sequentially outputs a scanning signal G for selecting a row to which the image signal S is to be supplied to the plurality of pixels PX for each row. For example, the scanning line driving circuit 180 transitions the potential of the scanning signal G1 to a selected potential such as high level in the first horizontal scanning period in which the video voltage is written to the pixels PX of the first row.

The control circuit 280 receives external signals such as a vertical synchronizing signal that defines a vertical scanning period and a horizontal synchronizing signal that defines a horizontal scanning period from an external host CPU device (not shown). The control circuit 280 synchronously controls the scanning line driving circuit 180, the image signal circuit 140, and the precharge circuit 160 based on signals received from the host CPU device.

For example, the control circuit 280 controls the timing of supplying the image signal S to the eight signal lines 122 included in each signal line group, that is, the k signal lines 122 using the write selection signal SEL or the like. The control circuit 280 outputs write selection signals SEL1 to SEL8 for selecting the signal line 122 of the series to which the image signal S is to be supplied to the write switches SWv of each series. For example, when the image signal S is supplied to the signal line 122 of the first series, the control circuit 280 causes the potential of the write selection signal SEL1 to transition to the selection potential. As a result, the write switch SWv of the first series transitions to the conducting state, and the image signal S output from the signal line driving circuit 240 is supplied to the signal line 122 of the first series.

Note that the control circuit 280 adjusts the length of the period during which the image signal S is supplied to the signal lines 122 of each series by adjusting the period during which the write selection signal SEL is maintained at the selection potential. That is, in the horizontal scanning period, the control circuit 280 performs k supply periods for sequentially supplying the image signal S to each of the eight signal lines 122 included in each signal line group, that is, to each of the k signal lines 122. controls the length of For example, the control circuit 280 may set one of the first supply period and the last supply period of the k supply periods to one or more than the first supply period and the last supply period of the k supply periods. longer than the prescribed supply period of

Further, the control circuit 280 outputs precharge selection signals PSEL1 to PSEL8 for selecting the signal line 122 of the series to which the precharge signal PRC is to be supplied, to the precharge switches SWp of each series. For example, when supplying the precharge signal PRC to the signal line 122 of the second series, the control circuit 280 causes the potential of the precharge selection signal PSEL2 to transition to the selection potential. As a result, the second series write switch SWv transitions to the conductive state, and the precharge signal PRC output from the precharge voltage control circuit 260 is supplied to the second series signal line 122 . Operation timings of the write selection signal SEL and the precharge selection signal PSEL will be described with reference to FIGS. 5 to 12. FIG.

FIG. 3 is a circuit diagram showing the configuration of the pixel PX. Each pixel PX has a liquid crystal element 130, a storage capacitor Cst connected to the capacitor line 124, and a pixel transistor TRh. The liquid crystal element 130 is an electro-optical element including a pixel electrode 132 and a common electrode 134 facing each other and a liquid crystal 136 arranged between the pixel electrode 132 and the common electrode 134 . As the transmittance of the liquid crystal 136 changes according to the voltage applied between the pixel electrode 132 and the common electrode 134, the display gradation changes. A common voltage Vcom, which is a constant voltage, is supplied to the common electrode 134 via a common line (not shown).

The storage capacitor Cst is provided in parallel with the liquid crystal element 130 . One terminal of the storage capacitor Cst is connected to the pixel transistor TRh, and the other terminal is connected to the common electrode 134 via the capacitor line 124 .

The pixel transistor TRh is, for example, an N-channel transistor including a TFT or the like, and is provided between the liquid crystal element 130 and the signal line 122 . The pixel transistor TRh is set to either a conducting state or a non-conducting state according to the level of the scanning signal G supplied to the scanning line 120 connected to the gate. That is, the pixel transistor TRh controls electrical connection between the liquid crystal element 130 and the signal line 122 . For example, by setting the scanning signal Gm to the selection potential, the pixel transistor TRh in each pixel PX of the m-th row transitions to the conductive state at the same time or almost at the same time.

When the pixel transistor TRh is controlled to be conductive, a video voltage based on the image signal S supplied from the signal line 122 is applied to the liquid crystal element 130 . The liquid crystal 136 is set to have a transmittance based on the image signal S when a video voltage based on the image signal S is applied. When a light source (not shown) is turned on, light emitted from the light source passes through the liquid crystal 136 of the liquid crystal element 130 of the pixel PX and is output to the outside of the electro-optical device 1 . That is, the pixel PX displays the gradation based on the image signal S by applying a video voltage based on the image signal S to the liquid crystal element 130 and turning on the light source.

A storage capacitor Cst provided in parallel with the liquid crystal element 130 is charged with the video voltage applied to the liquid crystal element 130 . That is, each pixel PX holds the potential corresponding to the image signal S in the holding capacitor Cst.

Note that when the pixel transistor TRh is controlled to be conductive, the holding capacitor Cst and the signal line 122 are electrically connected. Therefore, fluctuations in the potential E122 of the signal line 122 may propagate to the capacitance line 124 via the holding capacitance Cst. Further, the change in the potential E122 of the signal line 122 propagates to the capacitor line 124 due to the coupling capacitance between the signal line 122 and the capacitor line 124 (not shown). Although FIG. 2 shows an example of arrangement of capacitor lines in the row direction, it is particularly noticeable in the case of arranging the capacitor lines 124 in the column direction, that is, so as to overlap the signal lines 122 . In this case, there occurs a period during which the potential E124 of the capacity line 124 becomes unstable. Next, the potential variation of the capacitance line 124 accompanying the potential variation of the signal line 122 will be described with reference to FIG.

FIG. 4 is a diagram showing the relationship between the movement of the potential E122 of the signal line 122 and the movement of the potential E124 of the capacitance line 124. As shown in FIG. Note that FIG. 4 shows the relationship between the movement of the potential E122 of the signal line 122 and the movement of the potential E124 of the capacity line 124 when raster display is performed with positive polarity driving. Potential E122[i] indicates the potential E122 of the signal line 122 of the i-th series, and potential E122[j] indicates the potential E122 of the signal line 122 of the j-th series. In the example shown in FIG. 4, the image signal Si is supplied to the signal line 122 of the i-th series, and the precharge signal PRC is supplied to the signal line 122 of the j-th series. The video voltage Vvidp indicates a voltage based on the image signal Si during positive driving, and the precharge voltage Vprcp indicates a voltage based on the precharge signal PRC during positive driving. For example, the video voltage Vvidp is 12V and the precharge voltage Vprcp is 4V.

The potential E122[i] of the i-th series signal line 122 to which the video voltage Vvidp is applied transitions from the precharge voltage Vprcp to the video voltage Vvidp when the image signal Si for applying the video voltage Vvidp is supplied. do. In this case, the potential E124 of the capacitance line 124 rises from the common voltage Vcom and returns to the common voltage Vcom again.

Further, when the precharge signal PRC for applying the precharge voltage Vprcp is supplied, the potential E122[j] of the j-th series signal line 122 to be precharged changes from the video voltage Vvidp to the precharge voltage Vprcp. transition to In this case, the potential E124 of the capacity line 124 drops from the common voltage Vcom and returns to the common voltage Vcom again.

When the precharge signal PRC is supplied, the potential E124 of the capacitor line 124 changes by the same amount or the same amount as the change of the potential E124 of the capacitor line 124 when the image signal Si is supplied. Therefore, by overlapping the precharge period, which is the supply period of the precharge signal PRC, with the supply period of the image signal S, the potential fluctuation of the capacitor line 124, that is, the noise superimposed on the capacitor line 124 is canceled. Hereinafter, the effect of canceling out noise superimposed on the capacitor line 124 by applying potential variations with the same or similar amounts of variation and opposite directions to the capacitor line 124 is also referred to as a counter-noise effect. When the counter noise effect is obtained, the potential fluctuation of the capacitance line 124 is suppressed and the potential E124 of the capacitance line 124 is stabilized earlier than when the counter noise effect is not obtained.

In a natural image or the like, the relationship between the potential variation of the capacitor line 124 when the image signal Si is supplied and the potential variation of the capacitor line 124 when the precharge signal PRC is supplied differs from the example shown in FIG. It is not always effective. However, a natural image or the like has a stronger random element than a solid image in which all pixels PX have the same pixel value. Therefore, in a natural image or the like, even if the counternoise effect is not obtained, there is less sense of incongruity in appearance compared to a solid image in which the counternoise effect is not obtained.

5 to 12 show the operation timing of each horizontal scanning period H of the electro-optical device 1 when performing raster display with positive polarity driving. The number in brackets of the potential E122 indicates the series of the signal line 122. FIG. For example, the potential E122[1] indicates the potential E122 of the signal line 122 of the first series, and the potential E122[8] indicates the potential E122 of the signal line 122 of the eighth series. 5 to 12, the image signal circuit 140 outputs the image signal to one signal line 122 out of the k signal lines 122 in each of the k supply periods included in the horizontal scanning period H. supply S. Further, the precharge circuit 160 performs k A precharge signal PRC is supplied to one of the signal lines 122 . The control circuit 280 adjusts the first supply period and the k-th supply period of the k supply periods included in the horizontal scanning period H to the first supply period of the k supply periods. It is made longer than the supply periods other than the period and the k-th supply period.

FIG. 5 is a diagram showing operation timings during the first horizontal scanning period H1. The first horizontal scanning period H1 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX of the first row. In the first horizontal scanning period H1, the potential of the scanning signal G1 supplied to the scanning line 120 of the first row is set to high level. The scanning signals G2-G2160 supplied to the scanning lines 120 other than the first row are maintained at low level.

During the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL1-SEL8 are switched in order. That is, supply periods are assigned in order to the signal lines 122 of each series from the signal line 122 of the first series to the signal line 122 of the eighth series. As a result, the image signal S is sequentially supplied to the signal lines 122 of each series.

Further, the high level periods of the precharge selection signals PSEL2 to PSEL8 are switched in accordance with the switching of the high level periods of the write selection signals SEL1 to SEL7. For example, the precharge selection signal PSEL2 transitions to high level in synchronization with the timing at which the write selection signal SEL1 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL1 is maintained at low level.

During the supply period of the first series, that is, the period in which the write selection signal SEL1 is at a high level, the signal line 122 of the first series is not precharged. The same video voltage Vvidp is applied again to the signal line 122 of the first series. Therefore, the potential E122[1] of the signal line 122 of the first series hardly fluctuates. Therefore, the potential fluctuation of the capacitance line 124 due to the capacitive coupling between the first series signal line 122 and the capacitance line 124 hardly occurs. By the way, in the first horizontal scanning period H of each frame, in order to create a state in which the potential E122 of the signal line 122 hardly fluctuates, a dummy pixel row that is not visible in the display is provided and the same image signal S as in the raster display or a gray level signal is applied. is written to the signal line 122 . Alternatively, it is preferable to perform an operation such as writing the same image signal S as for raster display or a gray level signal to the signal line 122 before the first horizontal scanning period H of each frame starts.

In addition, during the supply period of the first series, the signal line 122 of the second series is precharged during the precharge period of the second series in which the precharge selection signal PSEL2 is maintained at a high level. That is, the precharge signal PRC is supplied to the signal line 122 of the second series during the precharge period of the second series. Therefore, the potential E122[2] of the second series signal line 122 transitions from the video voltage Vvidp to the precharge voltage Vprcp as described with reference to FIG. Then, due to capacitive coupling between the signal line 122 and the capacitor line 124 of the second series, the change in the potential E122[2] is propagated to the capacitor line 124, and the potential change occurs in the capacitor line 124. As described with reference to FIG. 4, the potential E124 of the capacitance line 124 drops from the common voltage Vcom and then returns to the common voltage Vcom.

During the supply period of the second series, that is, the period in which the write selection signal SEL2 is at high level, the video voltage Vvidp is applied to the signal line 122 of the second series charged to the precharge voltage Vprcp. Therefore, the potential E122[2] of the second series signal line 122 transitions from the precharge voltage Vprcp to the video voltage Vvidp as described with reference to FIG. Then, due to capacitive coupling between the signal line 122 and the capacitor line 124 of the second series, the change in the potential E122[2] is propagated to the capacitor line 124, and the potential change occurs in the capacitor line 124.

However, in the second series supply period, the third series signal line 122 is precharged during the third series precharge period that overlaps with the second series supply period. Therefore, due to the counter noise effect described with reference to FIG. 4, fluctuations in the potential E124 of the capacitor line 124 are suppressed compared to the supply period of the first series.

For example, in the supply period of the second series, the precharge of the signal line 122 of the third series is performed while the precharge selection signal PSEL3 is at high level. Therefore, the potential E122[3] of the third series signal line 122 transitions from the video voltage Vvidp to the precharge voltage Vprcp. Then, due to capacitive coupling between the signal line 122 and the capacitor line 124 of the third series, the change in the potential E122[3] is propagated to the capacitor line 124, and the potential change occurs in the capacitor line 124. The potential fluctuation of the capacity line 124 caused by the fluctuation of the potential E122[2] and the potential fluctuation of the capacity line 124 caused by the fluctuation of the potential E122[3] in the opposite direction to the fluctuation of the potential E122[2] are superimposed on each other. As explained, the noise generated in the capacitance line 124 is canceled.

During the supply period of the second series, fluctuations in the potential E124 of the capacity line 124 are suppressed compared to the supply period of the first series, so the potential E124 of the capacity line 124 stabilizes early. Therefore, the length T2 of the supply period of the second series can be made shorter than the length T1 of the supply period of the first series. Note that if the supply period ends before the potential E124 of the capacity line 124 stabilizes, that is, before the potential E124 of the capacity line 124 returns to the common voltage Vcom, the potential E124 of the capacity line 124 rises to the common voltage after the end of the supply period. Return to Vcom. In this case, the potential of the pixel electrode 132 connected to the storage capacitor Cst also fluctuates after the supply period ends. That is, the potential of the pixel electrode 132 changes from the video voltage Vvidp based on the image signal S after the end of the supply period. In this case, the pixel PX cannot display the gradation specified by the image signal S accurately.

Therefore, in the supply period of the first series, by making the length T1 of the supply period longer than the length T2 of the supply period of the second series, the supply period ends before the potential E124 of the capacitor line 124 stabilizes. suppress As a result, even in each pixel PX of the first series to which the image signal S is supplied during the supply period of the first series, the gradation specified by the image signal S can be accurately displayed.

From the supply period of the 3rd series to the supply period of the 7th series, as in the supply period of the 2nd series, the fluctuation of the potential E124 of the capacitance line 124 is suppressed compared to the supply period of the 1st series due to the counter noise effect. be done. As described above, the supply periods of the 2nd to 7th series are supply periods in which the image signal S is supplied to the signal line 122 already supplied with the precharge signal PRC. It includes an overlapping period with the precharge period for supplying the charge signal PRC.

During the supply period of the eighth series, that is, the period in which the write selection signal SEL8 is at the high level, the video voltage Vvidp is applied to the signal line 122 of the eighth series charged to the precharge voltage Vprcp. Therefore, the potential E122[8] of the eighth series signal line 122 transitions from the precharge voltage Vprcp to the video voltage Vvidp. Then, due to capacitive coupling between the signal line 122 and the capacitor line 124 of the eighth series, the change in the potential E122[8] is propagated to the capacitor line 124, and the potential change occurs in the capacitor line 124. For example, the potential E124 of the capacity line 124 rises from the common voltage Vcom and returns to the common voltage Vcom again.

In the supply period of the eighth series, precharging of the signal lines 122 of other series is not executed. Therefore, the counter noise effect cannot be obtained during the supply period of the eighth series. As a result, in the supply period of the eighth series, the time required for the potential E124 of the capacity line 124 to stabilize is longer than in the supply periods of the second to seventh series in which the counter noise effect is obtained. Therefore, in the supply period of the eighth series, by making the length T3 of the supply period longer than the length T2 of the supply period of the second series, the supply period ends before the potential E124 of the capacitor line 124 stabilizes. suppress As a result, it is possible to accurately display the gradation specified by the image signal S in each pixel PX of the eighth series to which the image signal S is supplied during the supply period of the eighth series.

That is, the control circuit 280 makes the supply period length T1 of the first series and the supply period length T3 of the eighth series longer than the supply period length T2 of the second series to the seventh series. In the example shown in FIG. 5, the supply period of the first series is the first supply period of eight supply periods for sequentially supplying the image signal S to each series of the eight signal lines 122. The supply period of the eighth series is the last supply period of the eight supply periods. The supply periods of the second series to the seventh series are supply periods excluding the first supply period and the last supply period of the eight supply periods.

That is, in the example shown in FIG. 5, the supply period of the first system is an example of the first supply period, the supply periods of the second system to the seventh system are examples of the predetermined supply period, and the supply periods of the eighth system are examples of the predetermined supply period. is an example of the last supply period. Therefore, the control circuit 280 sets the lengths T1, T3 of both the first and last feed periods of the eight feed periods to the lengths of the first and last feed periods of the eight feed periods. It is made longer than the length T2 of the predetermined supply period excluding the period. Note that the control circuit 280 may make the length of one of the first supply period and the last supply period of the eight supply periods longer than the predetermined supply period length T2.

FIG. 6 is a diagram showing operation timings during the second horizontal scanning period H2. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. The second horizontal scanning period H2 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the second row. In the second horizontal scanning period H2, the potential of the scanning signal G2 supplied to the scanning line 120 of the second row is set to high level. The scanning signals G1, G3-G2160 supplied to the scanning lines 120 other than the second row are maintained at low level.

In the second horizontal scanning period H2, the order of supplying the image signals S to the signal lines 122 of the first to eighth series is different from that in the first horizontal scanning period H1. For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL2-SEL8 and SEL1 are switched in this order. That is, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the first supply period between the two horizontal scanning periods H, the first horizontal scanning period H1 and the second horizontal scanning period H2. In addition, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the last supply period between the two horizontal scanning periods H, the first horizontal scanning period H1 and the second horizontal scanning period H2.

The high level periods of the precharge selection signals PSEL3 to PSEL8 and PSEL1 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL2 to SEL8. For example, the precharge selection signal PSEL3 transitions to high level in synchronization with the timing at which the write selection signal SEL2 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL1 transitions to high level in synchronization with the timing at which the write selection signal SEL8 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL2 is maintained at low level.

Therefore, in the second horizontal scanning period H2, the counter noise effect cannot be obtained in the first supply period, which is the second supply period, and the first supply period, which is the last supply period. On the other hand, a counter noise effect is obtained during the supply period from the third line to the eighth line. Therefore, the control circuit 280 makes the length T1 of the supply period of the second series and the length T3 of the supply period of the first series longer than the length T2 of the supply periods of the third series to the eighth series. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. It should be noted that the supply periods from the third series to the eighth series shown in FIG. 6 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied during the first supply period differs between the two horizontal scanning periods H, the pixel PX to which the image signal S is supplied during the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the two horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

At the operation timings shown in FIGS. 5 and 6, the control circuit 280 sets the supply period of the second series for supplying the image signal S to the signal line 122 of the second series to the first supply period during the second horizontal scanning period H2. , and a predetermined supply period in the first horizontal scanning period H1. Then, the control circuit 280 makes the initial supply period length T1 longer than the predetermined supply period length T2. Further, the precharge circuit 160 does not supply the precharge signal PRC to the signal lines 122 of the second series during the second horizontal scanning period H2, and supplies the precharge signal PRC to the signal lines 122 of the second series during the first horizontal scanning period H1. supplies the precharge signal PRC. 5 and 6, the signal line 122 of the second series is an example of the first signal line 122 of the k signal lines 122, and the second horizontal scanning period H2 is 2 H1 is an example of a first horizontal scanning period H that is one of the two horizontal scanning periods H, and the first horizontal scanning period H1 is an example of a second horizontal scanning period H that is the other of the two horizontal scanning periods H. .

FIG. 7 is a diagram showing operation timings in the third horizontal scanning period H3. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. The third horizontal scanning period H3 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the third row. In the third horizontal scanning period H3, the potential of the scanning signal G3 supplied to the scanning line 120 of the third row is set to high level. The scanning signals G1, G2, G4-G2160 supplied to the scanning lines 120 other than the third row are maintained at low level.

In the third horizontal scanning period H3, the order in which the image signal S is supplied to the signal lines 122 of each series from the first series to the eighth series is the first horizontal scanning period H1 and the second horizontal scanning period H2. different from For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL3-SEL8, SEL1, and SEL2 are switched in this order. That is, the control circuit 280 causes the signal line 122 to which the image signal S is supplied during the first supply period to differ between the three horizontal scanning periods H. FIG. Also, the control circuit 280 causes the signal line 122 to which the image signal S is supplied in the last supply period to differ between the three horizontal scanning periods H. FIG.

The high level periods of the precharge selection signals PSEL4 to PSEL8, PSEL1 and PSEL2 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL3 to SEL8 and SEL1. For example, the precharge selection signal PSEL4 transitions to high level in synchronization with the timing at which the write selection signal SEL3 transitions to high level, and transitions to low level after a predetermined time has elapsed. Further, for example, the precharge selection signal PSEL2 transitions to high level in synchronization with the timing at which the write selection signal SEL1 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL3 is maintained at low level.

Therefore, in the third horizontal scanning period H3, the counter noise effect cannot be obtained in the supply period of the third series, which is the first supply period, and the supply period of the second series, which is the last supply period. On the other hand, the counter noise effect is obtained in the supply periods of the 4th to 8th series and the supply period of the 1st series. Therefore, the control circuit 280 sets the length T1 of the supply period of the third series and the length T3 of the supply period of the second series to the length of the supply period of the fourth series to the eighth series and the supply period of the first series. The length of each supply period is made longer than T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. Note that the supply periods of the fourth to eighth series and the supply period of the first series shown in FIG. 7 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the first supply period differs in the three horizontal scanning periods H, the pixel PX to which the image signal S is supplied in the first supply period Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the three horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

FIG. 8 is a diagram showing operation timings in the fourth horizontal scanning period H4. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. A fourth horizontal scanning period H4 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the fourth row. In the fourth horizontal scanning period H4, the potential of the scanning signal G4 supplied to the scanning line 120 of the fourth row is set to high level. The scanning signals G1-G3 and G5-G2160 supplied to the scanning lines 120 other than the fourth row are maintained at low level.

In the fourth horizontal scanning period H4, the order in which the image signals S are supplied to the signal lines 122 of each series from the first series to the eighth series is changed from the first horizontal scanning period H1 to the third horizontal scanning period H3. different from each horizontal scanning period H up to. For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL4-SEL8 and SEL1-SEL3 are switched in this order. That is, the control circuit 280 causes the signal line 122 to which the image signal S is supplied during the first supply period to differ between the four horizontal scanning periods H. FIG. In addition, the control circuit 280 causes the signal line 122 to which the image signal S is supplied in the last supply period to differ between the four horizontal scanning periods H. FIG.

The high level periods of the precharge selection signals PSEL5 to PSEL8 and PSEL1 to PSEL3 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL4 to SEL8 and SEL1 to SEL2. For example, the precharge selection signal PSEL5 transitions to high level in synchronization with the timing at which the write selection signal SEL4 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL3 transitions to high level in synchronization with the timing at which the write selection signal SEL2 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL4 is maintained at low level.

Therefore, in the fourth horizontal scanning period H4, the counter noise effect cannot be obtained in the supply period of the fourth series, which is the first supply period, and the supply period of the third series, which is the last supply period. On the other hand, the counter noise effect is obtained in the supply periods of the 5th to 8th series, the supply period of the 1st series, and the supply period of the 2nd series. Therefore, the control circuit 280 sets the length T1 of the supply period of the fourth series and the length T3 of the supply period of the third series to the supply periods of the fifth series to the eighth series, the supply period of the first series, and the length of the supply period T3 of the third series. The supply period of the second series is made longer than the length T2 of each supply period. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. The fifth to eighth supply periods, the first supply period, and the second supply period shown in FIG. 8 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the first supply period is changed in the four horizontal scanning periods H, the pixel PX to which the image signal S is supplied in the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the four horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

FIG. 9 is a diagram showing operation timings in the fifth horizontal scanning period H5. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. A fifth horizontal scanning period H5 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the fifth row. In the fifth horizontal scanning period H5, the potential of the scanning signal G5 supplied to the scanning line 120 of the fifth row is set to high level. The scanning signals G1-G4 and G6-G2160 supplied to the scanning lines 120 other than the fifth row are maintained at low level.

In the fifth horizontal scanning period H5, the order in which the image signals S are supplied to the signal lines 122 of each series from the first series to the eighth series is changed from the first horizontal scanning period H1 to the fourth horizontal scanning period H4. different from each horizontal scanning period H up to. For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL5-SEL8 and SEL1-SEL4 are switched in this order. That is, the control circuit 280 causes the signal line 122 to which the image signal S is supplied in the first supply period to differ between the five horizontal scanning periods H. FIG. In addition, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the last supply period for each of the five horizontal scanning periods H. FIG.

The high level periods of the precharge selection signals PSEL6 to PSEL8 and PSEL1 to PSEL4 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL5 to SEL8 and SEL1 to SEL3. For example, the precharge selection signal PSEL6 transitions to high level in synchronization with the timing at which the write selection signal SEL5 transitions to high level, and transitions to low level after a predetermined time has elapsed. Further, for example, the precharge selection signal PSEL4 transitions to high level in synchronization with the timing at which the write selection signal SEL3 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL5 is maintained at low level.

Therefore, in the fifth horizontal scanning period H5, the counter noise effect cannot be obtained in the supply period of the fifth series, which is the first supply period, and the supply period of the fourth series, which is the last supply period. On the other hand, the counter noise effect is obtained in the supply period from the 6th line to the 8th line and the supply period from the 1st line to the 3rd line. Therefore, the control circuit 280 sets the length T1 of the supply period of the fifth series and the length T3 of the supply period of the fourth series to the supply periods of the sixth to eighth series and the first to third series. It is made longer than the length of each supply period T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. Note that the supply period from the sixth line to the eighth line and the supply period from the first line to the third line shown in FIG. 9 are examples of the predetermined supply period.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the first supply period is changed in the five horizontal scanning periods H, the pixel PX to which the image signal S is supplied in the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the five horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

FIG. 10 is a diagram showing operation timings in the sixth horizontal scanning period H6. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. A sixth horizontal scanning period H6 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the sixth row. In the sixth horizontal scanning period H6, the potential of the scanning signal G6 supplied to the scanning line 120 of the sixth row is set to high level. The scanning signals G1-G5 and G7-G2160 supplied to the scanning lines 120 other than the sixth row are maintained at low level.

In the sixth horizontal scanning period H6, the order in which the image signals S are supplied to the signal lines 122 of each series from the first series to the eighth series is changed from the first horizontal scanning period H1 to the fifth horizontal scanning period H5. different from each horizontal scanning period H up to. For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL6-SEL8 and SEL1-SEL5 are switched in this order. That is, the control circuit 280 changes the signal line 122 to which the image signal S is supplied during the first supply period for the six horizontal scanning periods H. FIG. In addition, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the last supply period for each of the six horizontal scanning periods H. FIG.

The high level periods of the precharge selection signals PSEL7, PSEL8, PSEL1 to PSEL5 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL6 to SEL8 and SEL1 to SEL4. For example, the precharge selection signal PSEL7 transitions to high level in synchronization with the timing at which the write selection signal SEL6 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL5 transitions to high level in synchronization with the timing at which the write selection signal SEL4 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL6 is maintained at low level.

Therefore, in the sixth horizontal scanning period H6, the counter noise effect cannot be obtained in the supply period of the sixth series, which is the first supply period, and the supply period of the fifth series, which is the last supply period. On the other hand, the counter noise effect is obtained in the supply period of the 7th line, the supply period of the 8th line, and the supply periods of the 1st line to the 4th line. Therefore, the control circuit 280 sets the length T1 of the supply period of the sixth series and the length T3 of the supply period of the fifth series to the supply period of the seventh series, the supply period of the eighth series, and the supply periods of the first series to the first series. The length of each supply period of up to four lines is made longer than T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. The supply period of the seventh series, the supply period of the eighth series, and the supply periods of the first to fourth series shown in FIG. 10 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied during the first supply period is made different in the six horizontal scanning periods H, the pixel PX to which the image signal S is supplied during the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the six horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

FIG. 11 is a diagram showing operation timings in the seventh horizontal scanning period H7. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. A seventh horizontal scanning period H7 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the seventh row. In the seventh horizontal scanning period H7, the potential of the scanning signal G7 supplied to the scanning line 120 of the seventh row is set to high level. The scanning signals G1-G6 and G8-G2160 supplied to the scanning lines 120 other than the 7th row are maintained at low level.

In the seventh horizontal scanning period H7, the order in which the image signals S are supplied to the signal lines 122 of each series from the first series to the eighth series is changed from the first horizontal scanning period H1 to the sixth horizontal scanning period H6. different from each horizontal scanning period H up to. For example, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL7, SEL8, and SEL1-SEL6 are switched in this order. That is, the control circuit 280 causes the signal line 122 to which the image signal S is supplied during the first supply period to differ between the seven horizontal scanning periods H. FIG. Also, the control circuit 280 causes the signal line 122 to which the image signal S is supplied in the last supply period to differ between the seven horizontal scanning periods H. FIG.

The high level periods of the precharge selection signals PSEL8 and PSEL1 to PSEL6 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL7, SEL8 and SEL1 to SEL5. For example, the precharge selection signal PSEL8 transitions to high level in synchronization with the timing at which the write selection signal SEL7 transitions to high level, and transitions to low level after a predetermined time has elapsed. Further, for example, the precharge selection signal PSEL6 transitions to high level in synchronization with the timing at which the write selection signal SEL5 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL7 is maintained at low level.

Therefore, in the seventh horizontal scanning period H7, the counter noise effect cannot be obtained in the supply period of the seventh series, which is the first supply period, and the supply period of the sixth series, which is the last supply period. On the other hand, a counter noise effect is obtained during the supply period of the eighth series and the supply periods of the first to fifth series. Therefore, the control circuit 280 sets the length T1 of the supply period of the seventh series and the length T3 of the supply period of the sixth series to the length of the supply period of the eighth series and the supply periods of the first to fifth series. The length of each supply period is made longer than T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. Note that the supply period of the eighth series and the supply periods of the first to fifth series shown in FIG. 11 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied during the first supply period differs in the seven horizontal scanning periods H, the pixel PX to which the image signal S is supplied during the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period is changed in seven horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

FIG. 12 is a diagram showing operation timings in the eighth horizontal scanning period H8. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted. The eighth horizontal scanning period H8 is a horizontal scanning period H for writing the video voltage Vvidp to the pixels PX on the eighth row. In the eighth horizontal scanning period H8, the potential of the scanning signal G8 supplied to the eighth scanning line 120 is set to high level. The scanning signals G1-G7 and G9-G2160 supplied to the scanning lines 120 other than the eighth row are maintained at low level.

In the eighth horizontal scanning period H8, the order in which the image signals S are supplied to the signal lines 122 of each series from the first series to the eighth series is changed from the first horizontal scanning period H1 to the seventh horizontal scanning period H7. different from each horizontal scanning period H up to. For example, during the high level period of each of the write selection signals SEL1 to SEL8, the write selection signals SEL8 and SEL1 to SEL7 are switched in this order. That is, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the eight horizontal scanning periods H in the first supply period. In addition, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the last supply period for each of the eight horizontal scanning periods H. FIG. That is, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the first supply period for k horizontal scanning periods H, and the signal line 122 to which the image signal S is supplied in the last supply period. are made different in k horizontal scanning periods H.

The high level periods of the precharge selection signals PSEL1 to PSEL7 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL8 and SEL1 to SEL6. For example, the precharge selection signal PSEL1 transitions to high level in synchronization with the timing at which the write selection signal SEL8 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL7 transitions to high level in synchronization with the timing at which the write selection signal SEL6 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signal PSEL8 is maintained at low level.

Therefore, in the eighth horizontal scanning period H8, the counter noise effect is not obtained in the supply period of the eighth series, which is the first supply period, and the supply period of the seventh series, which is the last supply period. On the other hand, a counter noise effect is obtained during the supply period from the first to the sixth series. Therefore, the control circuit 280 makes the supply period length T1 of the eighth series and the supply period length T3 of the seventh series longer than the supply period length T2 of the first through sixth series. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. It should be noted that supply periods of the first to sixth series shown in FIG. 12 are examples of predetermined supply periods.

Further, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied during the first supply period differs in eight horizontal scanning periods H, the pixel PX to which the image signal S is supplied during the first supply period. Even if the gradation is not accurately displayed, it is possible to prevent the column of pixels PX whose gradation is not accurately displayed from being fixed. Similarly, in the electro-optical device 1, since the signal line 122 to which the image signal S is supplied in the last supply period differs between the eight horizontal scanning periods H, the pixels PX to which the image signal S is supplied in the last supply period are different. Even if the gradation is not displayed accurately in , it is possible to prevent the column of the pixels PX whose gradation is not accurately displayed from being fixed.

5 to 12, the control circuit 280 controls the precharge period and the The supply period that does not include the overlapping period of the precharge period is made longer than the supply period that includes the overlapping period with the precharge period. Further, the control circuit 280 controls the supply period for supplying the image signal S to the signal lines 122 of the series to which the precharge signal PRC is not supplied, among the supply periods including the overlap period with the precharge period. is longer than the supply period during which the image signal S is supplied to the signal lines 122 of the columns already supplied with .

In the horizontal scanning periods H other than the horizontal scanning period H from the first horizontal scanning period H1 to the eighth horizontal scanning period H8, except for the scanning signal G that selects the row of pixels PX to be written with the video voltage Vvidp, the horizontal scanning period H shown in FIG. to any one of the operation timings shown in FIG. Note that the vertical scanning period may include a horizontal scanning period H in which operation timings differ from the operation timings shown in FIGS. 5 to 12, for example, a horizontal scanning period H in which precharge is not performed.

5 to 12, the operation timing of each horizontal scanning period H of the electro-optical device 1 when performing raster display with negative drive is the video voltage Vvidp and the precharge voltage Vprcp at the time of negative drive. It will be explained by replacing with video voltage and precharge voltage respectively. During negative driving, the potential E122 of the signal line 122 hardly fluctuates depending on the gradation.

FIG. 13 is a flow chart showing an example of the operation of the electro-optical device 1 according to the first embodiment. The operation shown in FIG. 13 is an example of a driving method of the electro-optical device 1. FIG. Note that the operation shown in FIG. 13 is an example of a method of driving the electro-optical device 1 when setting the length of each of eight supply periods, that is, k supply periods, in each horizontal scanning period H. . The electro-optical device 1 repeats the operation shown in FIG. 13 in each horizontal scanning period H until the lengths of all k supply periods are set.

First, in step S100, the electro-optical device 1 determines whether the supply period of the signal line 122 to be driven is the first supply period among k supply periods. When the supply period of the signal line 122 to be driven is the first supply period, the electro-optical device 1 sets the supply period of the signal line 122 to be driven to length T1 in step S200. On the other hand, if the supply period of the signal line 122 to be driven is not the first supply period, the operation of the electro-optical device 1 proceeds to step S120.
In step S120, the electro-optical device 1 determines whether the supply period of the signal line 122 to be driven is the last supply period among k supply periods. If the supply period of the signal line 122 to be driven is the last supply period, the electro-optical device 1 sets the supply period of the signal line 122 to be driven to length T3 in step S220. On the other hand, if the supply period of the signal line 122 to be driven is not the last supply period, the electro-optical device 1 in step S240 sets the supply period of the signal line 122 to be driven to the length T2, which is shorter than the lengths T1 and T3. set to

That is, in each horizontal scanning period H, the electro-optical device 1 sets the first supply period and the last supply period of the k supply periods for sequentially supplying the image signal S to each of the k signal lines 122. , is longer than one or more predetermined supply periods excluding the first and last supply periods of the k supply periods.

Note that the operation of the electro-optical device 1 is not limited to the example shown in FIG. For example, steps S120 and S220 may be omitted. Alternatively, steps S100 and S200 may be omitted. That is, in each horizontal scanning period H, the electro-optical device 1 sets one of the first supply period and the last supply period of the k supply periods to the first supply period and the last supply period of the k supply periods. may be longer than one or more predetermined supply periods excluding the supply period of .

As described above, in the first embodiment, in the horizontal scanning period H, the control circuit 280 supplies the image signal S to each of the k signal lines 122 in order. is longer than one or more predetermined supply periods excluding the first and last supply periods of the k supply periods.

For example, the predetermined supply period is the supply period during which the image signal S is supplied to the signal line 122 already supplied with the precharge signal PRC, and the precharge period during which the precharge signal PRC is supplied to the other signal line 122 . including overlapping periods of Therefore, a counter-noise effect that cancels out noise superimposed on the capacitor line 124 is obtained during a predetermined supply period.

Note that the initial supply period and the final supply period during which the counter noise effect is not obtained are set longer than the predetermined supply period during which the counter noise effect is obtained, as described above. As a result, the electro-optical device 1 can prevent the first supply period and the last supply period in which the counternoise effect cannot be obtained from ending before the capacitance line 124 stabilizes. Therefore, even in the pixels PX to which the image signal S is supplied during the first supply period and the last supply period, the gradation specified by the image signal S can be accurately displayed. That is, the electro-optical device 1 can suppress the occurrence of display unevenness and improve the display quality.

Even if one of the first supply period and the last supply period is longer than one or a plurality of predetermined supply periods excluding the first supply period and the last supply period of the k supply periods, the supply period The occurrence of display unevenness can be suppressed as compared with the case where the length of . That is, the display quality of the electro-optical device 1 can be improved.

Also, the control circuit 280 causes the signal line 122 to which the image signal S is supplied in the first supply period to differ between the two horizontal scanning periods H. FIG. Therefore, even if the pixels PX to which the image signal S is supplied during the first supply period do not display the correct gradation, it is possible to prevent the columns of the pixels PX not displaying the correct gradation from being fixed. Similarly, the control circuit 280 causes the signal line 122 supplied with the image signal S in the last supply period to be different between the two horizontal scanning periods H. FIG. Therefore, even if the pixel PX to which the image signal S is supplied in the last supply period does not display the correct gradation, it is possible to prevent the column of the pixel PX not displaying the correct gradation from being fixed.

In addition, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the first supply period for k horizontal scanning periods H. FIG. Therefore, even if the pixels PX to which the image signal S is supplied during the first supply period do not display the correct gradation, it is possible to prevent the columns of the pixels PX not displaying the correct gradation from being fixed. Similarly, the control circuit 280 changes the signal line 122 to which the image signal S is supplied in the last supply period for k horizontal scanning periods H. FIG. Therefore, even if the pixel PX to which the image signal S is supplied in the last supply period does not display the correct gradation, it is possible to prevent the column of the pixel PX not displaying the correct gradation from being fixed.

<Second embodiment>
The configuration and operation of the electro-optical device 1 according to the second embodiment are the same as those of the above-described electro-optical device 1 according to the first embodiment, except for the timing at which the control circuit 280 supplies the precharge signal PRC to the signal line 122. .

FIG. 14 is a diagram showing operation timings during the first horizontal scanning period H1 in the second embodiment of the present invention. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted.

In the first horizontal scanning period H1, similarly to the operation timing shown in FIG. 5, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL1-SEL8 are switched in order. Further, the high level periods of the precharge selection signals PSEL2 to PSEL8 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL1 to SEL7. In the example shown in FIG. 14, the order in which the high level periods of the precharge selection signals PSEL2 to PSEL8 are switched is the same as the operation timing shown in FIG. 5, but the switching timing is different from the operation timing shown in FIG. .

For example, the precharge selection signal PSEL2 changes in synchronization with the write selection signal SEL1, similar to the operation timing shown in FIG. However, the precharge selection signal PSEL2 transitions to high level before the write selection signal SEL1 transitions to high level. Then, the precharge selection signal PSEL2 transitions to low level before the write selection signal SEL1 transitions to low level.

Also, for example, the precharge selection signal PSEL8 changes in synchronization with the write selection signal SEL7, similar to the operation timing shown in FIG. However, the precharge selection signal PSEL8 transitions to high level after the write selection signal SEL6 transitions to low level and before the write selection signal SEL7 transitions to high level. Then, the precharge selection signal PSEL8 transitions to low level before the write selection signal SEL7 transitions to low level. Each of the precharge selection signals PSEL3 to PSEL7 also changes at the same timing as the precharge selection signal PSEL8 with respect to the synchronized write selection signal SEL.

That is, in the second embodiment, the control circuit 280 causes the precharge period that overlaps with the first supply period to precede the first supply period while leaving the period that overlaps with the first supply period. In addition, the control circuit 280 causes the precharge period that overlaps with the predetermined supply period such as the supply period of the second series to precede the predetermined supply period, leaving the period that overlaps with the predetermined supply period.

If the driving capability of the precharge switch SWp is low, a sufficient counter noise effect may not be obtained. Therefore, in the second embodiment, by making the precharge period precede the supply period, compared to the case where the precharge period does not precede the supply period, the time required for the potential E124 of the capacitor line 124 to fluctuate gradually. ensure As a result, it is possible to prevent the supply period from ending before the potential E124 of the capacitor line 124 is stabilized. Therefore, each pixel PX can display the gradation specified by the image signal S accurately.

<Modification>
Each form illustrated above can be variously modified. Specific modification modes are exemplified below. Two or more aspects arbitrarily selected from the following examples can be combined as appropriate within a mutually consistent range.

<Modification 1>
15 and 16 are diagrams showing operation timings of the electro-optical device 1 in Modification 1 of the first embodiment. 15 and 16 show operation timings of the electro-optical device 1 when performing raster display with positive polarity driving. In Modification 1, precharging is performed every other supply period. That is, the precharge may be performed in accordance with one or more predetermined supply periods excluding the last supply period among the k supply periods. In the example shown in FIGS. 15 and 16, the precharge circuit 160 has h number of supply periods corresponding to the first to k−1 supply periods among the k number of supply periods included in the horizontal scanning period H. , the precharge signal PRC is supplied to one signal line 122 out of the k signal lines 122 in each of the precharge periods. However, h is an integer of 2 or more and k-1 or less. In addition, the control circuit 280 sets the supply period corresponding to the first precharge period among the k supply periods included in the horizontal scanning period H to the supply period corresponding to the second precharge period. Lengthen.

FIG. 15 is a diagram showing operation timings during the first horizontal scanning period H1 in Modification 1 of the first embodiment. Detailed descriptions of operations that are the same as those described with reference to FIG. 5 will be omitted.

In the first horizontal scanning period H1, similarly to the operation timing shown in FIG. 5, during the high level period of each of the write selection signals SEL1-SEL8, the write selection signals SEL1-SEL8 are switched in order. Further, the high level periods of the precharge selection signals PSEL3, PSEL5 and PSEL7 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL1, SEL3 and SEL5. That is, in the first horizontal scanning period H1 of Modification 1, the precharge signal PRC is sequentially supplied to the odd-numbered signal lines 122 .

For example, the precharge selection signal PSEL3 transitions to high level in synchronization with the timing at which the write selection signal SEL1 transitions to high level, and transitions to low level after a predetermined time has elapsed. Further, for example, the precharge selection signal PSEL5 transitions to high level in synchronization with the timing at which the write selection signal SEL3 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL7 transitions to high level in synchronization with the timing at which the write selection signal SEL5 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signals PSEL1, PSEL2, PSEL4, PSEL6, and PSEL8 are maintained at low level.

Therefore, in the first horizontal scanning period H1 of Modification 1, the counter noise effect occurs in the supply period of the first series, which is the first supply period, and the supply period of the seventh series, which is the last supply period in the odd number series. I can't get it. On the other hand, the counter noise effect is obtained in the supply period of the third series and the supply period of the fifth series. Therefore, the control circuit 280 sets the length T1 of the supply period of the first series and the length of the supply period T4 of the seventh series to the length of each supply period of the supply period of the third series and the supply period of the fifth series. be longer than T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. The supply period of the third series and the supply period of the fifth series shown in FIG. 15 are examples of predetermined supply periods.

In the case of raster display, the potential E122 of the signal line 122 hardly changes during the supply period of the even series in the first horizontal scanning period H1 of Modification 1, so the potential E124 of the capacitor line 124 also hardly changes. Therefore, the length of the supply period of the even series, for example, the length of the supply period T3 of the 8th series, which is the last supply period, is the length of each supply period of the 3rd series and the supply period of the 5th series. It may be the same as T2.

FIG. 16 is a diagram showing operation timings during the second horizontal scanning period H2 in Modification 1. As shown in FIG. A detailed description of the same operations as those described with reference to FIGS. 5 and 6 will be omitted.

In the second horizontal scanning period H2, similarly to the operation timing shown in FIG. 5, during the high level period of each of the write selection signals SEL1 to SEL8, the write selection signals SEL1 to SEL8 are switched in order. Further, the high level periods of the precharge selection signals PSEL4, PSEL6 and PSEL8 are switched in order in accordance with the switching of the high level periods of the write selection signals SEL2, SEL4 and SEL6. That is, in the second horizontal scanning period H2 of Modification 1, the precharge signal PRC is sequentially supplied to the even-numbered signal lines 122 .

For example, the precharge selection signal PSEL4 transitions to high level in synchronization with the timing at which the write selection signal SEL2 transitions to high level, and transitions to low level after a predetermined time has elapsed. Further, for example, the precharge selection signal PSEL6 transitions to high level in synchronization with the timing at which the write selection signal SEL4 transitions to high level, and transitions to low level after a predetermined time has elapsed. Also, for example, the precharge selection signal PSEL8 transitions to high level in synchronization with the timing at which the write selection signal SEL6 transitions to high level, and transitions to low level after a predetermined time has elapsed. Note that the precharge selection signals PSEL1, PSEL2, PSEL3, PSEL5, and PSEL7 are maintained at low level.

Therefore, in the second horizontal scanning period H2 of Modification 1, the counter noise effect occurs in the supply period of the second series, which is the first supply period in the even series, and the supply period of the eighth series, which is the last supply period in the even number series. I can't get it. On the other hand, the counter noise effect is obtained in the supply period of the 4th series and the supply period of the 6th series. Therefore, the control circuit 280 sets the length T5 of the supply period of the second series and the length of the supply period T3 of the eighth series to the length of each supply period of the supply period of the fourth series and the supply period of the sixth series. be longer than T2. As a result, each pixel PX of each series can display the gradation specified by the image signal S accurately. The supply period of the fourth series and the supply period of the sixth series shown in FIG. 15 are examples of predetermined supply periods.

In the case of raster display, the potential E122 of the signal line 122 hardly changes during the supply period of the odd series in the second horizontal scanning period H2 of Modification 1, so the potential E124 of the capacity line 124 also hardly changes. Therefore, the length of the supply period of the odd series, for example, the length T1 of the supply period of the first series, which is the first supply period, is the length of each supply period of the supply period of the fourth series and the supply period of the sixth series. It may be the same as T2.

Also in Modification 1, it is possible to obtain the same effect as in the above-described first embodiment. In addition, you may apply the modification 1 to 2nd Embodiment mentioned above. That is, also in Modification 1, the control circuit 280 may cause the precharge period to precede the synchronous write selection signal SEL, leaving an overlapping period.

Also in Modification 1, the control circuit 280 may change the signal line 122 to which the image signal S is supplied in the first supply period in the odd series in a plurality of horizontal scanning periods H. In addition, the control circuit 280 may change the signal line 122 to which the image signal S is supplied in the first supply period in the even-numbered series in a plurality of horizontal scanning periods H. Also, the control circuit 280 may change the signal line 122 to which the image signal S is supplied in the last supply period in the odd-numbered series in a plurality of horizontal scanning periods H. In addition, the control circuit 280 may change the signal line 122 to which the image signal S is supplied in the last supply period in the even-numbered series in a plurality of horizontal scanning periods H.

<Modification 2>
Although FIG. 2 described above shows an example in which the other ends of the precharge switches SWp1-SWp4160 are connected to each other, the connection relationship of the other ends of the precharge switches SWp1-SWp4160 is not limited to the example shown in FIG. For example, the other ends of the precharge switches SWp connected to the signal lines 122 of odd-numbered columns are connected to each other, and the other ends of the precharge switches SWp connected to the signal lines 122 of even-numbered columns are connected to each other. good too.

In this case, during normal operation of the electro-optical device 1, the precharge voltage control circuit 260 is connected to the other end of the precharge switch SWp connected to the signal line 122 of the odd-numbered column and the signal line 122 of the even-numbered column. A precharge signal PRC is supplied to both the other end of the precharge switch SWp connected to . When testing the electro-optical device 1, for example, a test circuit (not shown) connects the other end of the precharge switch SWp connected to the signal line 122 of the odd-numbered column to the signal line 122 of the even-numbered column. electrically insulated from the other end of the precharge switch SWp. The test circuit differs from the other end of the precharge switch SWp connected to the signal line 122 of the odd-numbered column and the other end of the precharge switch SWp connected to the signal line 122 of the even-numbered column. Provides a level test signal. In this case, it is possible to easily detect a short circuit or the like between the signal lines 122 adjacent to each other.

<Modification 3>
Although FIG. 2 described above shows an example in which the plurality of signal lines 122 are classified into a signal line group including k signal lines 122, the plurality of signal lines 122 need not be classified into a plurality of signal line groups. good too. For example, the electro-optical device 1 may have k signal lines 122 to which the image signals S are supplied in order. That is, in the block diagram shown in FIG. 2, the signal lines 122 and the pixels PX from the 9th to 4160th columns, the write selection circuits SUv other than the write selection circuit SUv1, and the precharge selection circuits other than the precharge selection circuit SUp1 Circuit SUp may be omitted.

<Modification 4>
In the above-described first and second embodiments, a device using liquid crystal was exemplified as an electro-optical device, but the present invention is not limited to this. That is, any electro-optical device using an electro-optical material whose optical characteristics change with electrical energy may be used. The electro-optical material is a material whose optical characteristics such as transmittance and luminance change with the supply of an electrical signal such as a current signal or a voltage signal. For example, the present invention can be applied to display panels using light-emitting elements such as organic EL (ElectroLuminescent), inorganic EL, and light-emitting polymers, as in the first and second embodiments described above.

In addition, the electrophoretic display panel using microcapsules containing a colored liquid and white particles dispersed in the liquid as an electro-optical material is similar to the above-described first and second embodiments. The present invention can be applied. Furthermore, the present invention can also be applied to a twist ball display panel using, as an electro-optical material, twist balls in which different colors are applied to regions with different polarities, in the same manner as in the above-described first and second embodiments. can be applied. The present invention can also be applied to various electro-optical devices such as a toner display panel using black toner as an electro-optical material in the same manner as in the first and second embodiments described above.

<Modification 5>
During the development process of the present invention, the signal line 122 and the capacitor line 124 are affected by noise caused by the transition operation of the precharge switch SWp from the conducting state to the non-conducting state, and display unevenness is visually recognized. I know it can happen. Hereinafter, the transition operation in which the precharge switch SWp transitions from the conducting state to the non-conducting state is also referred to as the off-operation of the precharge switch SWp.
Modification 5 describes a method for suppressing the occurrence of display unevenness.

In FIG. 5 of the first embodiment described above, in the first series supply period, the second series signal line 122 is precharged in the second series precharge period. The end time of the supply period of the first series, that is, the timing immediately after the write selection signal SEL1 transitions to low level, coincides with the end time of the precharge period of the second series, that is, the precharge selection signal PSEL2 is at low level. later than the timing immediately after the transition to . On the other hand, the end time of the supply period of the second line and the end time of the precharge period of the third line are substantially the same.
Further, the inventor of the present application considers that when the end time of the n-th series supply period is later than the end time of the (n+a)-th series precharge period executed in the period overlapping with the n-th series supply period, the Compared to the case where the end time of the supply period of the n series coincides with the end time of the precharge period of the (n+a)th series that overlaps with the supply period of the nth series, the precharge switch SWp is turned off. The inventors have found that the influence of noise on the signal line 122 and the capacitor line 124 due to the noise increases. However, n is an integer of 1 or more, and a is an integer of 1 or more. The effect of noise on the signal line 122 and the capacitor line 124 due to the off operation of the precharge switch SWp is such that the end time of the supply period of the n-th series overlaps with the supply period of the n-th series. It is known that even if the end time of the precharge period of the (n+a)th series is earlier than the end time, it is suppressed.

Therefore, in order to suppress the influence of noise accompanying the OFF operation of the precharge switch SWp, in FIG. good too. Similarly, in FIG. 6, the end time of the precharge period of the third series may be substantially coincident with the end time of the supply period of the second series. Similarly, in FIG. 7, the end time of the precharge period of the fourth line may be substantially coincident with the end time of the supply period of the third line. Similarly, in FIG. 8, the end time of the precharge period of the fifth line may be substantially coincident with the end time of the supply period of the fourth line. Similarly, in FIG. 9, the end time of the precharge period of the sixth line may be substantially coincident with the end time of the supply period of the fifth line. Similarly, in FIG. 10, the end time of the precharge period of the seventh line may be substantially coincident with the end time of the supply period of the sixth line. Similarly, in FIG. 11, the end time of the precharge period of the eighth line may be configured to substantially coincide with the end time of the supply period of the seventh line. Similarly, in FIG. 12, the end time of the precharge period of the first series may be made substantially coincident with the end time of the supply period of the eighth series.
In this way, the time difference between the end time of the supply period for a certain series and the end time of the precharge period in which the period overlaps is aligned, or the end time of the supply period is overlapped. Display unevenness can be suppressed by adopting a configuration in which the end time of the precharge period is earlier than the end time of the precharge period.

<Application example>
INDUSTRIAL APPLICABILITY This invention can be used in various electronic devices. 17 to 19 illustrate specific forms of electronic equipment to which the present invention is applied.

FIG. 17 is an explanatory diagram of an example of an electronic device. 17 is a perspective view of a portable personal computer 2000 employing the electro-optical device 1. FIG. A personal computer 2000 has an electro-optical device 1 that displays various images, and a main body 2010 in which a power switch 2001 and a keyboard 2002 are installed.

FIG. 18 is an explanatory diagram showing another example of the electronic device. 18 is a perspective view of the mobile phone 3000. FIG. A mobile phone 3000 has a plurality of operation buttons 3001 and scroll buttons 3002, and an electro-optical device 1 that displays various images. By operating the scroll button 3002, the screen displayed on the electro-optical device 1 is scrolled.

FIG. 19 is an explanatory diagram showing another example of the electronic device. FIG. 19 is a schematic diagram showing the configuration of a projection display device 4000 employing the electro-optical device 1. As shown in FIG. The projection display device 4000 is, for example, a three-panel projector. An electro-optical device 1R shown in FIG. 19 is an electro-optical device 1 corresponding to a red display color, an electro-optical device 1G is an electro-optical device 1 corresponding to a green display color, and an electro-optical device 1B is The electro-optical device 1 corresponds to the display color of blue.

That is, the projection display device 4000 has three electro-optical devices 1R, 1G, and 1B corresponding to red, green, and blue display colors, respectively. The illumination optical system 4001 supplies the red component r of the light emitted from the illumination device 4002 as a light source to the electro-optical device 1R, the green component g to the electro-optical device 1G, and the blue component b to the electro-optical device 1B. supply to Each of the electro-optical devices 1R, 1G, and 1B functions as an optical modulator such as a light valve that modulates each monochromatic light supplied from the illumination optical system 4001 according to the display image. A projection optical system 4003 synthesizes the emitted light from each of the electro-optical devices 1R, 1G, and 1B and projects it onto a projection surface 4004 . That is, the present invention can also be applied to liquid crystal projectors.

In addition to the devices illustrated in FIGS. 1 and 17 to 19, electronic devices to which the present invention is applied include personal digital assistants (PDA). Other examples include digital still cameras, televisions, video cameras, car navigation systems, in-vehicle displays (instrument panels), electronic notebooks, electronic paper, calculators, word processors, workstations, videophones, and POS terminals. Furthermore, printers, scanners, copiers, video players, devices with touch panels, and the like are included.

Reference Signs List 1, 1B, 1G, 1R... Electro-optical device 100... Electro-optical panel 120... Scanning line 122... Signal line 124... Capacity line 130... Liquid crystal element 132... Pixel electrode 134... Common electrode 136... Liquid crystal 140 Image signal circuit 160 Precharge circuit 180 Scanning line driving circuit 200 Driving integrated circuit 240 Signal line driving circuit 260 Precharge voltage control circuit 280 Control circuit 300 DESCRIPTION OF SYMBOLS Flexible circuit board 2000 Personal computer 2001 Power switch 2002 Keyboard 2010 Main unit 3000 Mobile phone 3001 Operation button 3002 Scroll button 4000 Projection display device 4001 Illumination optical system , 4002... Lighting device 4003... Projection optical system 4004... Projection surface Cst... Storage capacitor PX... Pixel SUp... Precharge selection circuit SUv... Write selection circuit SWp... Precharge switch SWv... Write switch TRh: pixel transistor.

Claims (11)

a plurality of scan lines;
k (k is an integer of 3 or more) signal lines;
a reference line to which a reference potential is applied;
a pixel including a storage capacitor arranged corresponding to each intersection of the plurality of scanning lines and the k signal lines and connected to the reference line, the pixel holding a potential corresponding to an image signal in the storage capacitor; ,
an image signal circuit for sequentially supplying image signals to the k signal lines during k supply periods based on k selection signals for sequentially selecting the k signal lines in a horizontal scanning period;
a precharge circuit that supplies a precharge signal in a predetermined order to the signal lines of the k signal lines before the image signal circuit supplies an image signal in the horizontal scanning period;
In the horizontal scanning period, at least one of a first supply period and a last supply period among the k supply periods for sequentially supplying image signals to each of the k signal lines is set to the k supply periods. a control circuit for controlling the k selection signals to be longer than a predetermined supply period excluding the first supply period and the last supply period of the period;
with
The control circuit causes a precharge period that overlaps with the first supply period to precede the first supply period while leaving a period that overlaps with the first supply period, and a precharge period that overlaps with the predetermined supply period. controlling the k selection signals so that the period precedes the predetermined supply period while leaving a period overlapping the predetermined supply period;
The end time of the supply period and the end time of the precharge period that overlaps with the supply period are the same.
An electro-optical device characterized by: The control circuit controls the k selection signals so that both the first supply period and the last supply period are longer than the predetermined supply period.
2. The electro-optical device according to claim 1, wherein: The control circuit controls the k selection signals so that the signal line to which the image signal is supplied in the first supply period is different between the two horizontal scanning periods.
3. The electro-optical device according to claim 1, wherein: The control circuit controls the k selection signals so that the signal line to which the image signal is supplied in the first supply period is different in the k horizontal scanning periods.
4. The electro-optical device according to claim 1, wherein: The control circuit controls the k selection signals so that the signal lines to which the image signals are supplied in the last supply period are different between the two horizontal scanning periods.
5. The electro-optical device according to claim 1, wherein: The control circuit controls the k selection signals so that the signal line to which the image signal is supplied in the last supply period is different for the k horizontal scanning periods.
6. The electro-optical device according to claim 1, wherein: The control circuit sets the supply period for supplying the image signal to the first signal line of the k signal lines to the first supply period in the first horizontal scanning period, which is one of the two horizontal scanning periods. and the second horizontal scanning period, which is the other of the two horizontal scanning periods, is assigned to the predetermined supply period, and the k selection signals so that the first supply period is longer than the predetermined supply period. to control the
The precharge circuit does not supply a precharge signal to the first signal line during the first horizontal scanning period, and supplies a precharge signal to the first signal line during the second horizontal scanning period. supply,
7. The electro-optical device according to claim 1, wherein: An electronic apparatus comprising the electro-optical device according to claim 1 . a plurality of scan lines;
a plurality of signal lines in a group of k (k is an integer of 3 or more);
a reference line to which a reference potential is applied;
a pixel arranged corresponding to each intersection of the plurality of scanning lines and the plurality of signal lines, including a holding capacitor connected to the reference line, the pixel holding a potential corresponding to an image signal in the holding capacitor;
an image signal circuit that supplies an image signal to one of the k signal lines in each of k supply periods included in the horizontal scanning period;
The image of the k signal lines in each of the precharge periods corresponding to the first to k-1th supply periods of the k supply periods included in the horizontal scanning period. a precharge circuit that supplies a precharge signal to one signal line before the signal circuit supplies an image signal;
One of the first supply period and the k-th supply period of k supply periods included in the horizontal scanning period is replaced with the first supply period of the k supply periods. a control circuit for controlling the k supply periods to be longer than other supply periods excluding the period and the k-th supply period;
with
The control circuit causes a precharge period that overlaps with the first supply period to precede the first supply period while leaving a period that overlaps with the first supply period, and controlling the k selection signals so that a precharge period that overlaps with another supply period precedes the other supply period while leaving a period that overlaps with the other supply period;
The end time of the supply period and the end time of the precharge period that overlaps with the supply period are the same.
An electro- optical device characterized by: a plurality of scan lines;
a plurality of signal lines in a group of k (k is an integer of 3 or more);
a reference line to which a reference potential is applied;
a pixel arranged corresponding to each intersection of the plurality of scanning lines and the plurality of signal lines, including a holding capacitor connected to the reference line, the pixel holding a potential corresponding to an image signal in the holding capacitor;
an image signal circuit that supplies an image signal to one of the k signal lines in each of k supply periods included in the horizontal scanning period;
h precharges (h is an integer equal to or greater than 2 and equal to or less than k−1) corresponding to the first to k−1 supply periods among the k supply periods included in the horizontal scanning period; a precharge circuit that supplies a precharge signal to one of the k signal lines before the image signal circuit supplies an image signal in each of the periods;
The k number of supply periods included in the horizontal scanning period are set so that the supply period corresponding to the first precharge period is longer than the supply period corresponding to the second precharge period. a control circuit for controlling the supply period of
with
The control circuit sets each of the h precharge periods to the one supply period, leaving a period that overlaps with one corresponding one of the first to k-1th supply periods. controlling the k selection signals to precede the supply period of
The end time of the supply period and the end time of the precharge period that overlaps with the supply period are the same.
An electro-optical device characterized by : Corresponding to a plurality of scanning lines , k (k is an integer of 3 or more) signal lines , a reference line to which a reference potential is applied , and each intersection of the plurality of scanning lines and the k signal lines and a pixel that includes a holding capacitor connected to the reference line and holds a potential corresponding to an image signal in the holding capacitor; an image signal circuit for sequentially supplying image signals to the k signal lines in k supply periods based on k selection signals to be selected; and an image signal circuit for supplying the k signal lines in the horizontal scanning period and a precharge circuit for supplying precharge signals in a predetermined order to signal lines before the image signal circuit supplies an image signal , the method comprising:
In the horizontal scanning period, at least one of the first supply period and the last supply period among the k number of supply periods for sequentially supplying the image signal to each of the k number of signal lines is selected as the k number of supply periods. controlling the k selection signals to be longer than a predetermined supply period excluding the first supply period and the last supply period among the supply periods of
A precharge period that overlaps with the first supply period is caused to precede the first supply period while leaving a period that overlaps with the first supply period, and a precharge period that overlaps with the predetermined supply period is set to the predetermined period. controlling the k selection signals so as to precede the predetermined supply period, leaving a period overlapping the supply period of
The end time of the supply period and the end time of the precharge period that overlaps with the supply period are the same.
A method of driving an electro-optical device, characterized by:

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