JP2004004836A - Electro-optical device, driving method for the same, and electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electro-optical device having a function which can set only a part of a display screen to a display state and can set the other part to a non-display state, a driving method for the same, a driving method for a liquid crystal display device which uses a liquid crystal display device as the electro-optical device and can set a partial display state of low power consumption without a sense of incongruity in display, a liquid crystal display device on which display is performed by the driving method, and a driving circuit suitable for driving the electro-optical device. <P>SOLUTION: In the electro-optical device having a function which can set only a part of a display screen to a display state and can set the other part to a non-display state, an applied voltage to a scanning electrode is fixed to a non-selected voltage and an applied voltage to a signal electrode is fixed to the same voltage level as entire screen on indication or entire screen off indication at least for a prescribed period, with respect to a non-display area. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an electro-optical device having a function of setting only a part of a display screen to a display state and setting another part to a non-display state, and a driving method thereof. In addition, the present invention relates to a driving method of a liquid crystal display device that uses a liquid crystal display device as an electro-optical device and enables a low power consumption partial display state without a sense of incongruity in display, and a liquid crystal display device displayed thereby. Further, the present invention relates to a driving circuit suitable for driving the electro-optical device of the present invention.
[0002]
Further, the present invention relates to an electronic apparatus using the electro-optical device and the liquid crystal display device for a display device.
[0003]
[Prior art]
In display devices used in portable electronic devices such as mobile phones, the number of display dots has been increasing year by year so that more information can be displayed, and the power consumption by the display devices has increased accordingly. I'm coming. Since the power supply of the portable electronic device is generally a battery, the display device is strongly required to have low power consumption so that the battery life can be extended. For this reason, in a display device having a large number of display dots, the entire screen is set to the display state when necessary, but in a normal state, only a partial area of the display panel is set to the display state so that power consumption can be reduced, and other areas are set to the display state. A method of hiding the image is being considered. In addition, since a display device of a portable electronic device also needs low power consumption, a reflective type or a transflective type liquid crystal display panel which emphasizes an appearance in a reflective mode is used as a display panel.
[0004]
Many conventional liquid crystal display devices have a function of controlling display / non-display of the entire screen, but a function of setting only a part of the entire screen to a display state and setting other parts to a non-display state is provided. What we have has not yet been put to practical use. Patent Literature 1 and Patent Literature 2 have been proposed as methods for realizing a function of setting only a part of rows of a liquid crystal display panel to a display state and setting other rows to a non-display state. These two proposals are both methods in which the display duty is changed between the partial display and the full screen display, and the drive voltage and the bias ratio are changed in accordance with each duty.
[0005]
The driving method of Patent Document 1 will be described below with reference to FIGS. FIG. 19 is a block diagram of this conventional liquid crystal display device. A block 51 is a liquid crystal display panel (LCD panel) in which a substrate on which a plurality of scanning electrodes are formed and a substrate on which a plurality of signal electrodes are formed are arranged to face each other at an interval of several μm, and liquid crystal is sealed in the gap. Have been. The pixels (dots) are arranged in a matrix by the liquid crystal at the intersection of the scanning electrodes arranged in the row direction and the signal electrodes arranged in the column direction. Block 52 is a scan electrode drive circuit (Y driver) for driving the scan electrodes, and block 53 is a signal electrode drive circuit (X driver) for driving the signal electrodes. A plurality of voltage levels required for driving the liquid crystal are formed by a driving voltage forming circuit of a block 54 and applied to the liquid crystal display panel 51 via an X driver 53 and a Y driver 52.
Block 57 is a scanning control circuit for controlling the number of scanning electrodes to be scanned. A block 55 is a controller for supplying signals necessary for these circuits. FRM is a frame start signal, CLY is a scanning signal transfer clock, CLX is a data transfer clock, Data is display data, LP is a data latch signal, and PD is a data latch signal. Is a partial display control signal. Block 56 is the power supply for the above circuit.
[0006]
In this conventional example, the case where the partial display is the left half screen and the case where the partial display corresponds to the upper half screen is described here. Will be described. The number of scanning electrodes is 400. The controller 55 sets the partial display control signal PD to the “H” level to put the lower half screen in a non-display state. When the control signal PD is at the "L" level, the entire screen is displayed by scanning all the scanning electrodes at 1/400 duty. When the control signal PD is at the "H" level, the upper half of the panel is scanned. By scanning only the electrodes at a duty of 1/200, a partial display state is achieved in which the upper half screen is in a display state and the remaining lower half screen is in a non-display state. Switching to 1/200 duty is performed by doubling the period of the scanning signal transfer clock CLY and halving the number of clocks in one frame period. Although the details of the method of stopping scanning of the scanning electrodes in the lower half screen in the partial display state are not described, it is determined from the internal circuit diagram of the scanning control circuit block 57 that when the control signal PD is set to “H” level, the Y driver The data to be transferred from the 200th to 201st stages of the shift register is fixed at the “L” level, and as a result, the 201st to 400th outputs of the Y driver supplied to the 201st to 400th scanning electrodes are not selected. This is a method of maintaining the voltage level.
[0007]
FIG. 20 shows an example of a driving voltage waveform when a horizontal line is displayed every other scanning electrode in the partial display state of the conventional example. A is a voltage waveform applied to one pixel in the upper half screen, and B is a voltage waveform applied to all pixels in the lower half screen. In the waveforms A and B in the figure, the thick lines indicate the scanning electrode driving waveform, and the thin lines indicate the signal electrode driving waveform.
[0008]
The selection voltage V0 (or V5) is applied to the scanning electrodes of the upper half screen one row at a time in each selection period (one horizontal scanning period: 1H), and the non-selection voltage V4 (or V1) is applied to the scanning electrodes of the other rows. ) Is applied. On / off information of each pixel of the selected row is sequentially applied to the signal electrode in synchronization with the horizontal scanning period. More specifically, while the voltage applied to the scanning electrodes in the selected row is V0, V5 is applied to the signal electrodes of ON pixels in the selected row and V3 is applied to the signal electrodes of OFF pixels in the selected row. While the voltage applied to the scanning electrodes in the selected row is V5, V0 is applied to the signal electrodes of the ON pixels and V2 is applied to the signal electrodes of the OFF pixels in the selected row. The voltage applied to the liquid crystal of each pixel is a difference voltage between the scanning voltage (selection voltage and non-selection voltage) applied to the scanning electrode and the signal voltage (on voltage and off voltage) applied to the signal electrode, and is basically , A pixel having a high effective voltage of the difference voltage is turned on, and a pixel having a low effective voltage is turned off.
[0009]
On the other hand, the effective voltage of the pixels in the lower half screen is considerably smaller than the effective voltage applied to the off pixels of the upper half screen because no selection voltage is applied to the scan electrodes as shown in FIG. 20B. , The lower half screen is completely hidden.
[0010]
As shown by the liquid crystal AC drive signal M, FIG. 20 is a diagram in which the signal polarity of the drive voltage is switched every selection period for 13 rows. In the case of high-duty driving in order to reduce flicker and crosstalk, it is necessary to switch the signal polarity of the driving voltage every ten or more rows as described above. Although the lower half screen is not displayed, the voltage applied to the scanning electrodes and signal electrodes in the non-display area changes as shown in FIG. 20B. These circuits operate and the liquid crystal of the pixel is charged and discharged, and there is a disadvantage that power consumption is not so reduced.
[0011]
In the simple matrix type liquid crystal display panel, when the display duty is switched, it is necessary to change the setting of the drive voltage. Hereinafter, this point will be described with reference to FIG. 21 which is an internal circuit of the drive voltage forming block 54.
[0012]
First, the configuration and functions of FIG. 21 will be described. Driving a liquid crystal display panel with a duty higher than about 1/30 duty requires six levels of voltages V0 to V5. The maximum voltage applied to the liquid crystal is V0-V5, and the input power supply voltage of +5 V is used as it is for V0. A voltage V5 at which the contrast is optimal is extracted from the input power supply of 0V and -24V by the variable resistor RV1 for contrast adjustment and the transistor Q1. The voltages of V0-V5 are divided by the resistors R1 through R5 to form intermediate voltages, and the driving capability of the intermediate voltages is increased by operational amplifiers OP1 through OP4 to output V1 through V4. The switches S2a and S2b are interlock switches, and one of R3a and R3b is connected in series with R2 and R4 according to the level of the signal PD. By making the resistance values of R3a and R3b different, V0 to V5 having different voltage division ratios can be formed according to the level of PD.
[0013]
There is a relationship between V0 and V5 such that V0-V1 = V1-V2 = V3-V4 = V4-V5, and the voltage division ratio (V0-V1) / (V0-V5) is called a bias ratio.
It is disclosed in Japanese Patent Publication No. 57-57718 that a preferable bias ratio is 1 / (1 + ΔN) when the duty is 1 / N. Therefore, if the resistance values of R3a and R3b are set to 1/400 duty and 1/200 duty, respectively, it is possible to drive with a preferable bias ratio in each duty.
[0014]
When switching the duty, it is necessary not only to switch the bias ratio but also to change the drive voltage (V0-V5) at the same time. If the duty is switched from 1/400 to 1/200 while the drive voltage is fixed, even if the bias ratio is switched to a preferable value, the display will be extremely poor in contrast. This is because the effective voltage applied to the liquid crystal becomes too high because the time during which the selection voltage is applied to the liquid crystal is doubled. In the conventional example, the necessity of switching the bias ratio and the means for realizing the bias ratio are described in detail, but the necessity of switching the drive voltage and the means for realizing the same are not described in detail.
[0015]
Specifically, assuming that the duty is 1 / N, in the case of N >> 1, it is necessary to adjust (V0−V5) substantially in proportion to ΔN. For example, if the optimum (V0-V5) in the case of 1/400 duty is 28V, it is necessary to adjust (V0-V5) to 28V / {2} 20V in the case of 1/200 duty. This voltage adjustment is performed by adjusting the variable resistor RV1 for contrast adjustment each time the display is switched between the full screen display state and the upper half screen display state, but this is very inconvenient for the apparatus user. It is. Although it is necessary to add a drive voltage automatic setting means, it is not as easy as the bias ratio switching means, so that the drive voltage forming circuit is greatly complicated. In this conventional publication, it is described that the power consumption can be further reduced in a half-screen display because a small driving voltage is required. However, the reduced voltage of 8 V is a considerable part of causing the contrast adjustment transistor Q1 to generate heat. Power consumption is not so much reduced.
[0016]
In the case where the partial display is as small as about ten rows to about 20 rows, if the duty is switched accordingly, the preferable bias ratio becomes 1/3 or 1/4. The voltage required for driving the liquid crystal is not 6 levels but 5 levels in the case of 1/4 bias and 4 levels in the case of 1/3 bias. When a five-level voltage is required, the resistance value of the resistor R3a and R3b that is connected at the time of partial display may be set to 0Ω, but when a four-level voltage is required, the resistor R3a or R3b may be used. Instead, means for setting the resistances R2 and R4 to 0Ω is required. Patent Document 2 describes a bias ratio switching unit and a driving voltage switching unit in such a case, but further description of the configuration will be omitted here.
[0017]
According to the above-described method, the function of setting only a part of the rows of the liquid crystal display panel to the display state and setting the other rows to the non-display state becomes possible, and the power consumption can be reduced to some extent. . However, there are problems that the drive voltage forming circuit is considerably complicated, the number of rows that can be partially displayed is limited in terms of hardware, and that low power consumption is still insufficient.
[0018]
Further, Patent Document 1 relates to a transmissive liquid crystal display panel, and Patent Document 2 only describes a method of partial display and does not disclose a display mode.
However, when importance is placed on high contrast in a liquid crystal display device of a transmission type or a reflection type, a normally black type display panel has conventionally been adopted. The reason is as follows.
In the case of the normally white type, the gap between the dots to which no voltage is applied becomes white, so that the white display portion in the screen is sufficiently white, but the black display portion is not sufficiently black, whereas the normally black portion is not fully black. In the case of the type, the gap between the dots to which no voltage is applied becomes black, so that the black display portion is sufficiently black, but the white display portion is not sufficiently white. Since a display having a higher contrast is obtained when the black display portion is sufficiently black than when the white display portion is sufficiently white, a higher contrast is obtained by using a normally black display panel. .
[0019]
A normally black type is a black display when the effective voltage applied to the liquid crystal is an off-voltage lower than the liquid crystal threshold, and becomes a white display when the applied voltage is increased and an on-voltage higher than the liquid crystal threshold is applied. Mode. On the other hand, the normally white type displays white when the effective voltage applied to the liquid crystal is an off-voltage lower than the liquid crystal threshold, and displays black when the effective voltage is increased and an on-voltage higher than the liquid crystal threshold is applied. Mode. For example, when a twisted nematic liquid crystal having a twist of approximately 90 degrees is used, the liquid crystal display panel has a pair of polarizing plates on both sides of the panel, and when the transmission axes of the pair of polarizing plates are arranged substantially in parallel, normally. A black type and a normally white type when arranged substantially orthogonally.
[0020]
FIG. 18 is a diagram showing a partial display state when a normally black liquid crystal display panel 107 is used. Since an off voltage or an effective voltage lower than that is applied to the liquid crystal in the non-display area, the non-display area displays black as shown in the figure. On the other hand, in a reflective liquid crystal display panel, it is necessary to display characters in black and a background in white in order to reflect incident light to make the display bright and easy to see. However, in the normally black reflective liquid crystal display panel, the background of the display area is white while the non-display area is black, resulting in an uncomfortable partial display state. Furthermore, in the display dots located at the boundary between the display area and the non-display area on the display screen, the black display of the dots constituting the characters in the display area and the black display of the dots in the non-display area are adjacent dots. Therefore, there is a problem that the characters displayed on the display dots at the boundary between the display area and the non-display area are very difficult to read because they are connected when visually recognized. It is necessary to apply an on-voltage to the liquid crystal in the non-display area in order to make the non-display area white display so that there is no sense of incongruity, but it cannot be said that the area which should be non-display basically is not in the non-display state. . If the non-display area is to be displayed in white, not only can the power consumption of the circuit for realizing it be reduced, but also the liquid crystal molecules are arranged in the horizontal direction in the off state and the on state as in the nematic liquid crystal. In the case where the liquid crystal is turned on, the permittivity of the liquid crystal in the on state is two to three times larger than the permittivity of the liquid crystal in the off state. , The power consumption of the entire display device does not decrease as much as in the full-screen display state or conversely increases.
[0021]
As described above, if a normally black display panel is simply employed to improve the contrast, a non-display area is black in a partial display state, giving a strange feeling. Further, when the non-display area is to be displayed in white without a sense of incongruity, it cannot be said that the partial display function is basically realized, and the purpose of reducing power consumption cannot be fulfilled.
[0022]
Therefore, an object of the present invention is to solve the above-described problems in the conventional technology and to provide an electro-optical device in which power consumption is significantly reduced during partial display. It is another object of the present invention to provide a highly versatile electro-optical device in which the size and position of the partial display can be set by software without complicating the drive voltage forming circuit for the partial display function.
[0023]
Another object of the present invention is to provide a liquid crystal display device capable of realizing a display without a sense of incongruity in a partial display state and significantly reducing power consumption when a liquid crystal display device is used as the electro-optical device.
[0024]
It is another object of the present invention to provide a configuration of a driving circuit suitable for driving the electro-optical device of the present invention.
[0025]
Another object is to provide an electronic device with low power consumption by using an electro-optical device or a liquid crystal display device having these partial display functions for a display device.
[Patent Document 1]
JP-A-6-95621
[Patent Document 2]
JP-A-7-281632
[0026]
[Means for Solving the Problems]
The present invention is directed to a method of driving an electro-optical device having a function in which a plurality of scan electrodes and a plurality of signal electrodes are arranged so as to intersect and partially function as a display area of a display screen. Apply a selection voltage during a selection period and apply a non-selection voltage during a non-selection period, and fix a voltage applied to all the scanning electrodes during a period other than the selection period of the scanning electrodes in the display area. The display screen is set to a partial display state by fixing voltages applied to all the signal electrodes for at least a predetermined period. According to the present invention, in the case of partial display in which only a partial region is a display region, the potentials of all the scanning electrodes and all the signal electrodes are fixed for at least a predetermined period, so that the liquid crystal layer or the electrode which is an electro-optical material is used. A period during which charging and discharging are not performed in the driving circuit and the like occurs, and power consumption is reduced accordingly.
[0027]
Further, in the driving method of the electro-optical device according to the present invention, it is preferable that the voltage of the scanning electrode during the period in which the voltage applied to all the scanning electrodes is fixed is the non-selection voltage. Since the voltage of the scanning electrode fixed in the case of the partial display is a non-selection voltage, the driving circuit can be configured with a simple circuit.
[0028]
Further, in the driving method of the electro-optical device according to the present invention, it is preferable that the non-selection voltage is at one level. During the access period of the non-display area, the non-selection voltage can be fixed at one level, so that there is no voltage change and low power consumption can be achieved.
[0029]
Further, in the driving method of the electro-optical device according to the present invention, the drive voltage forming circuit applied to the scan electrodes and the signal electrodes may include a period for fixing the applied voltages to all the scan electrodes and all the signal electrodes. It is preferable to stop the operation. More specifically, the drive voltage forming circuit has a charge pump circuit that generates a boosted voltage or a stepped-down voltage by switching connection of a plurality of capacitors in accordance with a clock. The operation is preferably stopped during a period in which the applied voltage to the scanning electrode and all the signal electrodes is fixed. By doing so, power consumption in the driving voltage forming circuit can be reduced during the partial display state. When a charge pump circuit is used for voltage step-up / step-down, useless power consumption can be reduced by stopping a timing clock for switching a capacitor.
[0030]
According to the present invention described above, one of the driving methods of the simple matrix type liquid crystal display device in which the non-selection voltage is only one level is called MLS (Multi-Line-Selection) driving in which scanning electrodes in a plurality of rows are simultaneously selected. The other is a method called SA (Smart-Addressing) driving in which scanning electrodes are selected row by row. International Patent Publication WO96 / 21880 has proposed that the power consumption of a liquid crystal display device can be significantly reduced by combining such a driving method with a driving voltage forming circuit constituted by a charge pump circuit. The present invention has been developed based on the method of WO96 / 21880 so as to be capable of supporting a partial display function, thereby further reducing power consumption.
[0031]
The period other than the selection period in the scan electrode of the display region is a period other than the period in which the selection voltage is applied to the display row (hereinafter, this period is referred to as a non-display row access period). By fixing the potentials of all the scanning electrodes and all the signal electrodes, the power consumption of the drive circuit during this period can be extremely reduced, and the power consumption of the electro-optical device is reduced. Furthermore, if the operation of the charge pump circuit of the drive voltage forming circuit is stopped during this period, the charging and discharging of the capacitor there is eliminated and the power consumption is further reduced. During this period, since the power consumption of the drive circuit is extremely small, the capacitor holding the drive voltage is hardly discharged, and even if the operation of the charge pump circuit is stopped, the change in the drive voltage is practically negligible.
[0032]
Further, in the electro-optical device driving method according to the present invention, a first display mode in which the entire display screen is in a display state, a partial area of the display screen in a display state, and other areas in a non-display state It is preferable that a time period for applying a selection voltage to each scanning electrode in the display area does not change between the first display mode and the second display mode. According to the present invention, the time during which the selection voltage is applied to the scan electrodes in the display area is the same in the case of full screen display and the case of partial display, that is, the duty is the same. Therefore, there is no need to change the bias ratio or the drive voltage during partial display, and the drive circuit and the drive voltage forming circuit do not have to be complicated.
[0033]
Further, in the driving method of the electro-optical device according to the present invention, the effective voltage applied to the liquid crystal of the pixel in the display area in the display state may be different between the first display mode and the second display mode. Similarly, it is preferable to set a potential to be applied to the signal electrode during a period other than the selection period of the scanning electrode in the display area. According to the present invention, the potential of the signal electrode is set so that the effective voltage applied to the liquid crystal, which is the electro-optical material in the display area, is the same in the case of full screen display and the case of partial screen display. Therefore, the contrast of the display area can be kept unchanged.
[0034]
Further, in the driving method of the electro-optical device according to the present invention, the potential applied to the signal electrode during a period other than the selection period of the scan electrode in the display area is set to the ON display or the OFF display in the first display mode. In this case, it is preferable to set the same as the voltage applied to the signal electrode. Since the signal voltage in the full-screen display state is used as it is, the driving circuit and the driving control are simplified.
[0035]
Further, in the driving method of the electro-optical device according to the present invention, the plurality of scanning electrodes are driven so as to be simultaneously selected for each predetermined number of units and sequentially selected for each predetermined number of units. The voltage applied to the signal electrode in the case of ON display or OFF display in the above is the same as the voltage applied to the signal electrode in the case of full screen ON display or full screen OFF display in the first display mode. preferable. By doing so, in the MLS driving method, the effective voltage applied to the liquid crystal in the display area of the display area can be made the same between the case of full screen display and the case of partial screen display, and the image quality in the case of partial screen display Can be kept good. The increase in the circuit scale is very small.
[0036]
Further, in the driving method of the electro-optical device according to the present invention, the potential applied to the signal electrode during a period other than the selection period of the scan electrode in the display area is set to a full screen display state for each predetermined period of one screen scan. It is preferable that the applied potential for ON display and the applied potential for OFF display are alternately switched and set. Further, in the electro-optical device driving method according to the present invention, the polarity of the voltage difference between the scanning electrode and the signal electrode during a period other than the selection period of the scanning electrode in the display area in the second display mode is It is preferable that it be inverted every frame. By doing so, power consumption during the non-display row access period can be significantly reduced. When the number of partial display rows is small (for example, about 60 rows or less), the image quality of the entire screen does not deteriorate even if the liquid crystal drive voltage of the pixels in the non-display rows is fixed.
[0037]
Further, according to the present invention, in a method for driving an electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to cross each other and having a function of partially setting a display screen as a display area, To the electrodes, a selection voltage is applied during a selection period and a non-selection voltage is applied during a non-selection period, and the scanning electrodes in other areas of the display screen are applied with the non-selection voltage without applying the selection voltage. Is applied, and for all the signal electrodes, the display screen is set to the partial display state by fixing the applied voltage for at least a period longer than the same polarity drive period in the polarity inversion drive in the full screen display state. It is characterized by the following. According to the present invention, in the case of partial display in which only a partial region is a display region, the potentials of all the scanning electrodes and all the signal electrodes are fixed for a predetermined period, so that the liquid crystal layer or the electrode which is an electro-optical material is used. A period occurs in which charging and discharging are not performed in the driving circuit and the like, and power consumption is correspondingly reduced.
[0038]
Further, in the driving method of the electro-optical device according to the present invention, the voltage applied to the signal electrode is set to a full-screen display at least every period longer than the same polarity drive period in the polarity inversion drive in the full-screen display state. It is preferable to alternately switch between the potential for ON display and the potential for OFF display in the state. Even during the non-display row access period, the polarity of the drive voltage is periodically inverted, so that application of a DC voltage to the liquid crystal and crosstalk can be prevented.
[0039]
The above driving method of the electro-optical device can be realized by a simple matrix type liquid crystal display device or an active matrix type liquid crystal display device.
[0040]
Further, the electro-optical device according to the present invention is driven by using the above-described method for driving an electro-optical device, whereby an electro-optical device with low power consumption can be provided.
[0041]
Further, in the electro-optical device according to the present invention, in the electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged so as to intersect with each other and having a function of partially using a display screen as a display area, A scan electrode drive circuit for applying a selection voltage to the electrodes during a selection period and applying a non-selection voltage during a non-selection period; and a signal electrode drive for applying a signal voltage according to display data to the plurality of signal electrodes. A circuit, setting means for setting position information of a partial display area in a display screen, and a part for controlling the scanning electrode driving circuit and the signal electrode driving circuit based on the position information set in the setting means. Control means for outputting a display control signal, wherein the scan electrode drive circuit and the signal electrode drive circuit respond to the partial display control signal, wherein the scan electrode and the signal in a display area in a display screen are provided. Driven so that the display corresponding to the display data electrode, is the scanning electrodes in the non-display area in the display screen, characterized in that a non-display state to continue applying a non-selection voltage. According to the present invention, it is not necessary to change the duty, the bias ratio, the liquid crystal drive voltage, and the like with a hardware circuit for partial display, so the number and positions of display rows or non-display rows are changed by the control circuit. It can be set in a register. By doing so, it is possible to provide a highly versatile electro-optical device in which the number and positions of partial displays can be set by software.
[0042]
The electro-optical device described above can be realized as a simple matrix type liquid crystal display device or an active matrix type liquid crystal display device.
[0043]
In addition, the driving circuit of the electro-optical device according to the present invention is configured such that a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect, and has a function of partially setting a display screen as a display area. A first drive unit for applying a voltage to the plurality of scan electrodes, and a storage circuit for display data, wherein a voltage selected according to the display data read therefrom is applied to the plurality of signal electrodes. A second driving unit for applying a voltage, wherein the first driving unit applies a selection voltage to a scanning electrode of the display region during a selection period and applies a non-selection voltage to a non-selection period, And a function of applying only the non-selection voltage to the scan electrodes in the other area of the display screen, and the second driving unit operates during a period corresponding to a selection period of the scan electrodes in the display area. Reading display data from the storage circuit; Out, the other periods, characterized in that it has a function of fixing the display data read address of the memory circuit. According to the present invention, the current consumption of the signal electrode drive circuit in the non-display row access period is reduced to almost 0 by stopping the operation of reading the display data from the storage circuit built in the signal electrode drive circuit. be able to. At this time, if the read display information is fixed to 1 or 0, the output of the signal electrode drive circuit can be fixed to the same potential as in the case of full screen on display or full screen off display.
[0044]
Further, in the electro-optical device according to the present invention, it is preferable that the shift operation of the shift register in the first driving unit is stopped during a period other than the selection period of the scan electrode in the display area. According to the present invention, since the scan electrode drive circuit does not output the selection voltage during this period, the shift register inside the scan electrode drive circuit does not need to operate. If the operation of the shift register is stopped by stopping the shift clock, the power consumption of the scan electrode driving circuit during this period can be reduced to almost zero.
[0045]
In addition, the driving circuit of the electro-optical device according to the present invention is configured such that a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect, and has a function of partially setting a display screen as a display area. , A scan electrode drive circuit for sequentially applying a selection voltage to the plurality of scan electrodes in accordance with a shift operation of a shift register, wherein the scan electrode drive circuit partially makes a display screen a display area In this case, a selection voltage is applied to a scan electrode in a display area of the display screen during a selection period in accordance with a shift operation of the shift register, and a shift voltage of the shift register is applied to scan electrodes in another area of the display screen. The operation is stopped halfway, and only the non-selection voltage is applied, and the scan electrode drive circuit shifts from a state in which a display screen is a partial display area to a full screen display state, Shi Characterized in that it has an initial setting unit that initial state Torejisuta. According to the present invention, at the time of transition from the partial display state to the full screen display state, scanning of the scanning electrodes can be started from the first row without starting scanning from intermediate scanning electrodes.
[0046]
According to another aspect of the invention, an electro-optical device includes a driving circuit of the above-described electro-optical device, and a scanning electrode and a signal electrode driven by the driving circuit, thereby enabling partial display and reducing power consumption. An electro-optical device can be provided.
[0047]
Further, in the electro-optical device according to the present invention, in the electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged so as to intersect with each other and having a function of partially using a display screen as a display area, First drive means for applying a voltage to the electrodes, and second drive for applying a voltage selected according to the display data read out from the storage circuit for display data to the plurality of signal electrodes Means for applying a selection voltage to a scanning electrode in a display area of the display screen during a selection period and applying a non-selection voltage to a scanning electrode during a non-selection period; Has a function of applying only the non-selection voltage to the scan electrodes in the other area, and the second drive means is provided for the plurality of signal electrodes in a selection period of the scan electrode in the display area. Read from the storage circuit Applying a voltage based on the display data, and having a function of applying a voltage based on the same display data in the other periods. According to the present invention, the current consumption of the signal electrode drive circuit in the non-display row access period is reduced to almost 0 by stopping the operation of reading the display data from the storage circuit built in the signal electrode drive circuit. be able to.
[0048]
Further, in the electro-optical device according to the present invention, during the period other than the selection period of the scan electrode in the display area, the second driving unit performs the same polarity driving period in the polarity inversion driving in the full screen display state. It is preferable that the voltage applied to the signal electrode be alternately switched between a potential for ON display and a potential for OFF display in a full-screen display state at least every long period. Even during the non-display row access period, the polarity of the drive voltage is periodically inverted, so that application of a DC voltage to the liquid crystal and crosstalk can be prevented.
[0049]
Further, in the electro-optical device according to the present invention, the electro-optical device further includes a driving voltage forming circuit that forms a voltage applied to the scanning electrode or the signal electrode and supplies the voltage to the driving unit. Preferably, the operation of the contrast adjustment circuit is stopped during a period other than the selection period of the scanning electrodes in the display area. Since the electro-optical device of the present invention consumes very little power in the driving circuit during the non-display row access period, if the driving voltage is held by a capacitor, the fluctuation of the driving voltage is small even if the contrast adjustment circuit is stopped during this period. There is no practical problem. By stopping the contrast adjustment circuit, the power consumption of the drive circuit can be further reduced.
[0050]
In addition, the method of driving a liquid crystal display device according to the present invention is a reflective or semi-transmissive device capable of performing a partial display state in which a partial area of the entire screen of a liquid crystal display panel is in a display state and other areas are in a non-display state. In the method of driving a liquid crystal display device of a liquid crystal display type, the liquid crystal display panel is a normally white type, and an effective voltage equal to or less than an off voltage is applied to the liquid crystal in the non-display area in the partial display state. . By employing the normally white type, the non-display area becomes white in the partial display state, so that it is possible to realize a display without a sense of incongruity. In addition, simple means with low power consumption can be used as a circuit means for applying an effective voltage equal to or less than the OFF voltage to the liquid crystal in the non-display area. Further, since the dielectric constant of the liquid crystal in the non-display area is small, AC driving of the liquid crystal can be performed. Accordingly, the charge / discharge current decreases, and the power consumption of the entire display device can be significantly reduced as compared with the case where the entire screen is in the display state.
[0051]
Further, in the driving method of the liquid crystal display device, it is preferable that the liquid crystal display panel is a simple matrix liquid crystal panel, and that only a non-selection voltage is applied to the scanning electrodes in the non-display area in the partial display state. Further, it is preferable that the liquid crystal display panel is a simple matrix type liquid crystal panel, and in the partial display state, only a voltage for turning off the signal is applied to the signal electrode in the non-display area.
[0052]
Further, in the driving method of the liquid crystal display device, the liquid crystal display panel is an active matrix type liquid crystal panel, and the liquid crystal of the pixels in the non-display area has an off-voltage or less in at least the first frame when the display mode shifts to the partial display state. It is preferable to apply only the non-selection voltage to the scanning electrodes in the non-display area from the subsequent frame. Further, the liquid crystal display panel is an active matrix type liquid crystal panel, and applies a voltage equal to or less than an off voltage to the liquid crystal of the pixels in the non-display area in at least the first frame when shifting to the partial display state. It is preferable that only a voltage equal to or lower than an off voltage is applied to the signal electrode during the access period of the non-display area.
[0053]
In this way, partial display areas can be provided in the row direction and the column direction of the display screen, and the other areas can be hidden. In addition, since it is a normally white liquid crystal display panel, the non-display area is displayed in white, so that there is little discomfort in display. In addition, since high voltage is not applied to pixels in the non-display area, power consumption can be reduced. Can be.
[0054]
Further, the liquid crystal display device of the present invention is driven by using the above-described method of driving a liquid crystal display device. Can be provided.
[0055]
Further, the electronic apparatus of the present invention can provide an electro-optical device using the above-described electro-optical device of the present invention or the above-described liquid crystal display device as a display device. In particular, when the electronic device uses a battery as a power source, the power consumption of the display device is reduced, so that the battery life can be significantly extended.
[0056]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings.
[0057]
FIG. 1 is a block diagram showing a liquid crystal display device as an example of an embodiment of an electro-optical device according to the present invention. First, the configuration will be described. Block 1 is a simple matrix type liquid crystal display panel (LCD panel) using super twisted nematic (STN) type liquid crystal, in which a substrate on which a plurality of scanning electrodes are formed and a substrate on which a plurality of signal electrodes are formed have a size of several μm. The liquid crystal is sealed in the gap, and the above-mentioned liquid crystal is sealed in the gap. Pixels (dots) are arranged in a matrix by the liquid crystal at the intersection of the plurality of scanning electrodes and the plurality of signal electrodes. Further, a polarizing element such as a retardation plate or a polarizing plate is arranged on the outer surface side of the substrate as needed.
[0058]
The liquid crystal is not limited to the STN used in the present embodiment, but may be any of various types such as a type in which liquid crystal molecules are twisted (TN type), a homeotropic type, a vertical type, and a memory type such as ferroelectric. be able to. Further, a light scattering liquid crystal such as a polymer dispersed liquid crystal may be used. The liquid crystal display panel may be of a transmissive type, a reflective type or a transflective type, but is preferably of a reflective type or a transflective type in order to reduce power consumption. When colorizing the liquid crystal display panel 1, a method of forming a color filter on the inner surface of the substrate, switching the three colors emitted by the lighting device in time series, and the like are conceivable.
[0059]
Block 2 is a scan electrode drive circuit (Y driver) for driving the scan electrodes of the liquid crystal display panel, and block 3 is a signal electrode drive circuit (X driver) for driving the signal electrodes of the liquid crystal display panel. A plurality of voltage levels required for driving the liquid crystal are formed by a driving voltage forming circuit of the block 4 and applied to the liquid crystal display panel 1 via the X driver 3 and the Y driver 2. Block 5 is a controller for supplying necessary signals to those circuits. PD is a partial display control signal, FRM is a frame start signal, CLX is a data transfer clock, and Data is display data. LP is a data latch signal, which also serves as a scanning signal transfer clock and a drive voltage forming circuit clock. Block 6 is the power supply for the above circuit.
[0060]
Although the controller 5, the drive voltage forming circuit 4, the X driver 3 and the Y driver 2 are shown as separate blocks, these need not be separate ICs, and the controller 5 may be replaced by the Y driver 2 or the X driver 3. Or the driving voltage forming circuit may be built in the Y driver 2 or the X driver 3, the X and Y drivers may be formed as one-chip ICs, and all these circuits may be formed as one. They may be combined in a chip IC. Further, these circuit blocks may be disposed on a separate substrate from the liquid crystal display panel 1, mounted on a substrate constituting the liquid crystal display panel 1 as an IC, or disposed with a circuit formed on the substrate. Good.
[0061]
Since the liquid crystal display device of the present invention is of a simple matrix type and uses a driving method in which only one level of voltage is applied to the scanning electrodes in the non-selected rows, the driving circuit is simplified and power consumption can be reduced. . The non-selection voltage may be prepared in two voltage levels corresponding to the polarity of the voltage applied to the liquid crystal, and a driving method of alternately selecting the non-selection voltage according to the polarity inversion may be adopted. In particular, such a driving method is conventionally used in an active matrix type liquid crystal display device having a two-terminal type non-linear element described later in a pixel.
[0062]
Further, the driving voltage forming circuit block 4 in FIG. 1 is constituted by a charge pump circuit whose main part raises or lowers the voltage. However, a step-up / step-down circuit other than the charge pump circuit may be used.
[0063]
As an example, the liquid crystal display panel 1 has a total of 200 rows (the number of scanning electrodes), and the entire screen is in a display state (full screen display mode) when necessary. Only the 40 lines are in the display state, and the remaining 160 lines are in the non-display state (partial display mode). A specific driving method will be described in the following individual embodiments.
[0064]
(1st Embodiment)
Here, referring to FIGS. 2 to 4, a driving method in which four rows of scanning electrodes are simultaneously selected and a simultaneous selection is sequentially performed in units of four rows of scanning electrodes (hereinafter referred to as a 4MLS (Multi-Line-Selection) driving method). The following describes an example of a case where partial display is performed using the following expression. First, an example of the driving voltage forming circuit 4 for 4MLS driving will be described with reference to the block diagram of FIG.
[0065]
In the MLS driving method, a non-selection voltage VC, a positive-side selection voltage VH (a positive-side voltage based on VC), and a negative-side selection voltage VL (based on VC) are used as a scanning signal voltage (scanning voltage output by the Y driver 2). Three voltage levels are required. Here, VH and VL are symmetric about VC. In the 4MLS driving method, five voltage levels of ± V2, ± V1, and VC are required as signal voltages (signal voltages output by the X driver 3), and the corresponding voltages of ± V2 and ± V1 are each centered on VC. It is symmetric. The circuit shown in FIG. 2 outputs the above voltage using (Vcc-GND) as the input power supply voltage and the data latch signal LP as the clock source of the charge pump circuit. Hereinafter, unless otherwise specified, the description is made on the assumption that GND is a reference (0 V) and Vcc = 3 V. GND and Vcc are used as they are for VC and V2 of the liquid crystal drive voltage, respectively.
[0066]
The block 7 is a step-up / step-down clock forming circuit that forms a two-phase clock having a narrow time interval for operating the charge pump circuit from the data latch signal LP. The block 8 is a negative-direction six-fold booster circuit, and uses Vcc-GND as the input power supply voltage to form VEE ≒ −15 V, which is six times the input power supply voltage in the negative direction with respect to Vcc. Hereinafter, the negative direction indicates the direction of the negative voltage with reference to a predetermined voltage, and the positive direction indicates the direction of the positive voltage similarly. The block 13 is a contrast adjustment circuit for extracting a necessary negative selection voltage VL (for example, -11 V) from VEE, and is constituted by a bipolar transistor and a resistor. The block 9 is a double boosting circuit that forms the positive-side selection voltage VH, and generates VH (for example, 11 V) that is twice the input voltage in the positive direction with respect to VL using (GND-VL) as the input voltage. I do.
[0067]
The block 10 is a negative direction double boosting circuit, and forms -V2 ≒ -3V, which is twice the input power supply voltage in the negative direction with respect to Vcc, with (Vcc-GND) as the input power supply voltage. The block 11 is a 1/2 step-down circuit, which uses (Vcc-GND) as an input power supply voltage and forms V1 ≒ 1.5 V, which is a voltage stepped down to 1/2. The block 12 is also a 1/2 step-down circuit, and uses [GND-(-V2)] as an input power supply voltage to generate -V1 ≒ -1.5V, which is a voltage stepped down to 1/2.
[0068]
Thus, a voltage required for the 4MLS driving method can be formed. Each of the blocks 8 to 12 is a charge pump type step-up / step-down circuit. Such a drive voltage forming circuit using a charge pump type step-up / step-down circuit has high power supply efficiency, so that the liquid crystal display device can be driven with low power consumption by the 4MLS driving method. Each of the charge pump circuits in the blocks 8 to 12 has a known configuration. In the case of a booster circuit, as an example, after connecting N capacitors in parallel and charging the input voltage, the N capacitors are connected. If it is connected in series, a boosted voltage N times the input voltage can be obtained. If it is a step-down circuit, N capacitors of the same capacity are connected in series, the input voltage is charged from both ends, and then N capacitors are connected in parallel. A 1 / N step-down voltage is obtained. The two-phase clock formed by the clock forming circuit 7 serves as a control clock for a switch that switches and connects these capacitors in series and in parallel.
[0069]
All or some of the circuit blocks 8 to 12 in the drive voltage forming circuit 4 may be replaced with a well-known switching regulator using a coil and a capacitor instead of the charge pump circuit.
[0070]
FIG. 3 is an example of a timing diagram of the liquid crystal display device shown in FIGS. 1 and 2 including a liquid crystal driving voltage waveform, and FIG. 4 is a diagram for explaining an example of a liquid crystal driving voltage waveform. FIG. 3 shows an example in which 200 rows of scanning electrodes are provided on the entire screen, and only 40 rows are in a display state, and horizontal lines are displayed every other scanning electrode in the display state area. The interval between the pulses of the frame start signal FRM is one frame period for scanning one screen, and its length is 200H (1H is one selection period or one horizontal scanning period).
[0071]
CA is a field start signal, and one frame is divided into four fields f1 to f4 of 50H each. The cycle of the data latch signal LP is 1H, and four rows of scan electrodes are simultaneously selected for each clock of the signal LP. The selection voltage VH or VL is applied to the scanning electrodes in the selected row, and the non-selection voltage VC is applied to the scanning electrodes in the other rows. Waveforms of Y1 to Y40 and Y41 to Y200 indicate scan voltage driving waveforms applied to the scan electrodes of rows 1 to 200. The scanning electrodes Y1 to Y4 at the first clock of the signal LP, Y5 to Y8 at the second clock,..., And the scanning electrodes Y37 to Y40 at the tenth clock are sequentially selected, and the selection of 40 rows goes round during 10H. While some of the 40 rows are selected, the partial display control signal PD is at the "H" level. During the 40 row selection period, the PD continues to be at the "H" level for 10H. When the selection of the 40 rows is completed, the PD becomes the “L” level, and the remaining period 40H of one field 50H continues the “L” level. Normally, the Y driver 2 has a control terminal for asynchronously fixing all outputs to the non-selection voltage VC by input of a control signal. By inputting the partial display control signal PD to such a control terminal of the Y driver 2, the non-display row access period 40H in 50H of one field f in which the signal PD is in the "L" period is a full scan of 200 rows. The electrodes are fixed at the non-selection level VC.
[0072]
M is a liquid crystal AC drive signal, and switches the polarity of the drive voltage (the difference between the scan voltage and the signal voltage) applied to the liquid crystal of the pixel between the “H” level and the “L” level. Xn is applied to the n-th signal electrode when only 1 to 40 rows are in a display state, 41 to 200 rows are in a non-display state, and a horizontal line is displayed every other scanning electrode in the display state. 3 shows a driving waveform of a signal electrode.
[0073]
Although the above operation is repeated in each field, the manner of applying the selection voltages VH and VL to be applied to the selected four rows of scanning electrodes differs in each of the fields f1 to f4. This is shown in FIG. 4A. The selection voltages to be applied to the selected scanning electrodes of the four rows are VH, VL, VH, and VH in the order from the first row to the fourth row in the field f1, but are selected from the first row to the fourth row in the field f2. The order is VH, VH, VL, VH in the row. The combination of the selection voltages in each field is referred to as a Com pattern. FIG. 4A shows a determinant in which VH is 1 and VL is -1. This Com pattern follows a certain orthonormal matrix.
[0074]
The signal voltage is determined by the display pattern and the Com pattern. When the display pattern is represented by a determinant of 4 rows and 1 column as shown in FIG. 4B with the ON pixel set to −1 and the OFF pixel set to 1, in each of the fields f1 to f4, the scan electrodes Y4n + 1 to n4 of the nth signal electrode Xn. The signal voltage applied to the pixels in the Y4n + 4th row can be represented by the product of the Com pattern matrix and the display pattern matrix as shown in FIG. 4C. Each row of the product matrix is a signal voltage to be applied to the signal electrode according to the display of the pixels in the four rows. For example, according to FIG. 4C, a signal voltage based on the calculation result of (d1-d2 + d3 + d4) is applied to the signal electrode Xn in the field f1, and a signal voltage based on the calculation result of (d1 + d2-d3 + d4) is applied in the field f2. , Fields f3 and f4, the signal voltage is determined based on the calculation result shown in FIG. 4C. In the calculation results, 0 means VC, ± 2 means ± V1, and ± 4 means ± V2.
[0075]
More specifically, for example, when the entire screen is displayed on (d1 to d4 are all -1), the operation result is -2 for all rows, so that the signal voltage is -V1 for all fields, and the entire screen is off. In the case of display (d1 to d4 are all 1), the operation result is 2 for all rows, and therefore the signal voltage is V1 in all fields. In the case of displaying a horizontal line every other scanning electrode (d1 = d3 = -1, d2 = d4 = 1), the operation result is -2 in the fields f1 and f4, so that the signal voltage is -V1, and the fields f2 and f3 Is 2, the signal voltage becomes V1.
[0076]
In FIG. 3, while the selection voltage is being applied to the scanning electrodes in the display area, the driving voltage selected as a result of the calculation according to the display pattern is applied to the signal electrodes Xn as described above. It is not preferable to fix the signal voltage in the non-display row access period 40H to VC. The signal voltage of the non-display row access period 40H is set in two states so that the contrast of the 1st to 40th rows displayed at the time of switching between the full screen display state and the partial display state does not change. This is because it is necessary that the effective voltage applied to the power supply becomes the same. Therefore, in this case, the signal voltage during that period is maintained at the voltage -V1 when the scan electrodes of the last four rows (Y37 to Y40) of the display area are selected. The signal voltage in the non-display row access period 40H is fixed to a constant voltage in one field, but is not always the same in each field. The drive voltage of the signal electrode Xn changes to -V1, V1, V1, and -V1 during the non-display row access period for each field. As described above, the signal voltage in the non-display row access period 40H does not need to be fixed to the same voltage in each field, and changes even when the polarity of the liquid crystal driving voltage described below is inverted.
[0077]
M is a liquid crystal AC drive signal, and FIG. 3 shows a case where the polarity of the liquid crystal drive voltage is inverted for each frame. When the level of the liquid crystal AC drive signal M is inverted, the polarity of the above-described Com pattern in FIG. 4A is inverted (1 is -1 and 1 is -1), and the selection applied to the scanning electrode and the signal electrode accordingly. The polarity of the voltage and the signal voltage with respect to VC is also inverted. In the full-screen display state, the liquid crystal AC drive signal M is inverted every 11H, and the polarity of the selection voltage applied to the liquid crystal is inverted every 11H, thereby reducing the occurrence of display crosstalk. On the other hand, in the partial display state, the polarity inversion drive is performed in the display region D every the same period (11H) as in the case of the full screen display, but in the non-display region, the voltage applied to the liquid crystal is longer than 11H. Reverse the polarity. If the partial display area is small, the non-display row access period becomes long, and the potentials of the signal electrodes and the scan electrodes are fixed for a long period after the display area D is driven at a high duty, and the polarity inversion is performed for each frame. However, as a result of the experiment, there was no problem in image quality.
Further, since the liquid crystal driving voltage is fixed during the non-display access period, the power consumption due to the charge / discharge current and the through current generated by the voltage change in the liquid crystal layer, the Y driver 2 and the X driver 3, the controller 5, and the like is reduced. Since it is greatly reduced, it is preferable in terms of low power consumption. The larger the non-display area, the longer the non-display access period and the longer the fixed period of the scanning voltage and the signal voltage, so that the charge and discharge of the liquid crystal and the circuit are suppressed and the power consumption can be further reduced.
[0078]
With the above method, a partial display function in the case of the 4MLS driving method can be realized. With such a method, the power consumption in the partial display state can be reduced to a level almost proportional to the number of display rows.
[0079]
When the liquid crystal display panel 1 is in the full-screen display state, the control signal PD is always at the "H" level, the data latch signal LP is continuously supplied, and the scanning electrodes Y1 to Y200 are simultaneously selected every four rows and the four rows are selected. Selected sequentially in units. In addition, in the full screen display state, it is necessary to invert the polarity of the liquid crystal drive voltage every predetermined period. For example, it is necessary to reverse the polarity by switching the polarity of the selection voltage and the signal voltage every 11H. In addition, the polarity of the liquid crystal drive electrode may be inverted every frame period, or in addition, the polarity may be inverted every predetermined period in the frame.
[0080]
The time and voltage for applying the selection voltage to each scanning electrode in the display area are the same in the case of full screen display and the case of partial display in only some rows. Therefore, there is no element that needs to be added to the drive voltage forming circuit 4 for the partial display function.
[0081]
In the above embodiment, the MLS driving method in the case of simultaneous selection of four lines has been described. However, the number of simultaneously selected lines is not limited to four. It does not matter. If the number of simultaneously selected lines is different, the period of one field is different. Although the case where the application of the selection voltage is uniformly distributed in one frame has been described, when the application of the selection voltage is not uniformly performed (for example, selection of Y1 to Y4 is continuously performed for 4H, selection of Y5 to Y8 is performed for the next 4H). The method is also applicable to a method in which selections are grouped in a frame so that the selection is performed continuously. Further, in the embodiment, the entire screen is 200 lines and the number of partial display lines is 40 lines. However, the present invention is not limited to this, and the position of the partial display is not limited to this.
[0082]
Further, in the above embodiment, the number of clocks of the data latch signal LP per field is described as (the number of display rows / the number of simultaneously selected lines). The case of addition is also included in the gist of the present invention.
[0083]
(Second embodiment)
Next, the present embodiment will be described with reference to FIGS. FIG. 5 is a circuit diagram showing a part of the controller 5 in FIG. 1, and is a circuit block for controlling a partial display state. FIG. 6 is a timing chart for explaining the operation of the circuit of FIG. 5, and is a view obtained by enlarging and adding a part of the timing chart of FIG. 3 of the first embodiment. The configuration and operation of the liquid crystal display device of the present invention are the same as those described in the first embodiment. Therefore, the description of the same parts as in the first embodiment will be omitted.
[0084]
First, the configuration of the circuit in FIG. 5 will be described. Reference numeral 14 denotes a register of about 8 bits, in which information indicating whether the display is in the partial display state and information corresponding to the number of lines to be partially displayed are set. If the number of rows is set by 7 bits, 2 is required for a line-sequentially driven panel for each row. ⁷ = Partial display of up to 128 lines can be set in units of one line. In a panel of 4 lines simultaneous selection drive (4MLS drive method) ⁷ Partial display up to × 4 = 512 lines can be set in units of four lines.
[0085]
Reference numeral 15 denotes a circuit block mainly including a counter, which forms timing signals PD and CNT for controlling partial display based on timing signals such as a field start signal CA and a data latch signal LPI and a set value of the register 14. LPI is a signal on which LP is based, and as shown in FIG. 6, is a signal in which a clock having a constant cycle exists even in a non-display row access period in which PD is at “L” level. 16 is an AND gate.
[0086]
As shown in FIG. 6, the partial display control signal forming block 15 first forms the signal CNT preceding the partial display control signal PD by 1H based on the field start signal CA, the data latch signal LPI, and the register set value. In the circuit block 15, CNT can be formed by, for example, switching the CNT level by detecting coincidence between a counter that counts the number of rows by inputting the LPI and the value of the row obtained by the setting value of the register 14. . The AND output between CNT and LPI becomes LP. PD is formed by delaying CNT by 1H with LPI. In the full screen display state, the CNT is constantly at the "H" level, the AND gate 16 remains open, and the same signal as the LPI is sent to LP as it is. Thereby, all the scanning electrodes of 200 rows are selected in units of a predetermined number of rows.
[0087]
In the case of partial display, the PD indicating the partial display period in one field period is set to the “H” level during the period specified by the set value, according to the set value of the shift register 14. The data latch signal LP is output only during the period when the CNT is "H" by controlling the output of the LP with the CNT having the "H" level of the length corresponding to the "H" level period. Become like
[0088]
According to the above method, a value corresponding to the number of lines of the partial display is set in the register 14 of the control circuit, and the number of lines of the partial display can be varied by adjusting the PD (CNT) according to the set value. In order to realize the partial display function, it is not necessary to provide a means having a hardware limitation such as a change of the LP cycle or a change of the bias ratio and the selection voltage. Thus, a liquid crystal display device having a versatile partial display function that can be set by software.
[0089]
Note that, in the above example, a case has been described where partial display is performed for a fixed number of lines from the top of the panel. By setting a value, the position of the partial display area can be made variable in addition to the number of lines. In this case, the circuit block 15 compares the count value of the counter with the start row set in the first register, sets CNT to “H” by a match, and sets the counter count value and the end set in the second register. Control is performed so that CNT is set to “L” by comparing with the row and matching.
[0090]
(Third embodiment)
The present embodiment is an example of a case different from the first embodiment only in that the potential of the signal electrode during the non-display row access period is fixed to the same level as in the case of full screen off display. The adoption of the 4MLS driving method of the uniform distribution of the selection voltage by the Com pattern in FIG. 4A and the driving voltage forming circuit 4 as shown in FIG. 2 mainly including a charge pump circuit, and there are 200 scanning electrodes on the entire screen. , Only 40 rows are in the display state, the horizontal line is displayed every other scanning electrode in the display state, and the length of one frame period is 200H. The first embodiment is the same as the first embodiment in that the voltage applied to the scan electrodes during the non-display row access period is fixed to the non-selection voltage VC, and the polarity of the liquid crystal drive voltage is inverted for each frame. is there. Therefore, the description of the same parts as in the first embodiment will be omitted.
[0091]
FIG. 7 shows a timing chart in the present embodiment, and differs from FIG. 3 described in the first embodiment only in the voltage waveform applied to the signal electrode Xn. Since the voltage waveforms applied to the scan electrodes Y1 to Y200 are the same as those in FIG. 3, the description in FIG. 7 is omitted.
[0092]
In the present embodiment, the potential applied to the signal electrode Xn during the non-display row access period (period of 40H in each field f) is fixed to the same level ± V1 as in the case of the full screen off display. That is, the signal voltage in the non-display row access period is fixed to V1 when the liquid crystal AC drive signal M is "L", and is fixed to -V1 when M is "H", and is inverted every frame. ing.
[0093]
With this method, the effective voltage applied to the liquid crystal in the display area can be made the same between the full screen display state and the partial display state, and the display area is switched between the full screen display and the partial display. Can be kept unchanged. It is possible to fix the signal voltage in the non-display row access period to the same voltage as in the case of full screen off display by adding a slight change to the X driver 3. One example of the method will be described in the sixth embodiment.
[0094]
The signal voltage in the non-display row access period is set to the same voltage as when the scan electrodes (Y37 to Y40) of the last four rows of the display area are selected as in the first embodiment. The method of setting the signal voltage to the same level as in the case of full screen off display or full screen on display as in this embodiment is preferable in that flicker can be suppressed.
[0095]
The reason is described below. If the display pattern of the last four lines of the partial display area is three lines on display and one remaining line is off display, or conversely, three lines are off display and one remaining line is on display In the first embodiment, the signal voltage is VC in three of the four fields, and the remaining one is -V2 or V2 in accordance with the number of ON rows in the last four rows of the partial display area. Therefore, the signal voltage in the non-display row access period is VC in three of the four fields, and -V2 or V2 in the remaining one field according to the number of ON rows of the last four rows of the partial display area.
[0096]
On the other hand, in the case of the present embodiment, as described above, -V1 (signal electrode voltage for all-pixel on display) or V1 (signal electrode voltage for all-pixel off display) in all four fields according to the liquid crystal AC drive signal M. ). Since the voltage of ± V2 in the first embodiment is twice as large as ± V1, the liquid crystal easily responds and causes flicker. Therefore, it is preferable in terms of image quality to set the signal voltage in the non-display row access period to the same voltage as in the case of full screen off display or full screen on display.
[0097]
(Fourth embodiment)
Here, an example in which partial display is performed using an SA (Smart-Addressing) driving method will be described. The configuration of the liquid crystal display device is the same as that of FIG. 1 described above. The SA driving method is different from the driving method of FIG. 20 in which the liquid crystal AC driving signal M is “H” in FIG. This is a driving method in which the potential is lowered by (V1-V4) as a whole and the non-selection voltage is set to one level, and the scanning electrodes are sequentially selected row by row as in the conventional driving. First, an example of a SA drive voltage generating circuit corresponding to the block 4 in FIG. 1 will be described with reference to FIG. 8 which is a block diagram thereof.
[0098]
Similarly to the MLS driving method, the SA driving method requires three voltage levels of a non-selection voltage VC, a positive-side selection voltage VH, and a negative-side selection voltage VL as scanning signal voltages. Here, VH and VL are symmetric about VC. VH in the case of the SA driving method is considerably higher than VH in the case of the MLS driving method. Two voltage levels of ± VX are required as signal voltages, and these voltages are also symmetric about VC. The circuit shown in FIG. 8 uses (Vcc-GND) as the input power supply voltage and outputs the above voltage using the data latch signal LP as the clock source of the charge pump circuit. Hereinafter, unless otherwise specified, description will be made on the assumption that GND is a reference (0 V) and Vcc = 3 V.
[0099]
GND and Vcc are used as they are for the signal voltages -VX and VX, respectively. The block 17 is a step-up / step-down clock forming circuit that forms a two-phase clock having a narrow time interval for operating the charge pump circuits 18 to 20 from the input signal LP. The block 19 is a 降 step-down circuit, and forms VC ≒ 1.5 V which is a voltage obtained by stepping down the input power supply voltage Vcc to １ ／. The block 18 is a negative-direction eight-fold booster circuit, and forms VEE ≒ -21V, which is eight times the input power supply voltage in the negative direction with respect to Vcc, using (Vcc-GND) as the input power supply voltage. The block 21 is a contrast adjusting circuit for extracting a necessary negative selection voltage VL (for example, -17 V) from VEE. The block 20 is a double boosting circuit that forms the positive-side selection voltage VH, and forms VH (for example, 20 V) that is twice the input voltage in the positive direction with respect to VL using (VC-VL) as the input voltage. I do.
[0100]
Thus, a voltage required for SA driving can be formed. Each of the blocks 18 to 20 is a charge pump type step-up / step-down circuit. The charge pump circuit is configured by series-parallel switching of a plurality of capacitors using a two-phase clock as described above. Such a charge pump type drive voltage generation circuit using a step-up / step-down circuit has high power supply efficiency, so that a liquid crystal display device using the SA drive method can be driven with low power consumption.
[0101]
FIG. 9 is an example of a timing diagram including a liquid crystal drive voltage waveform. There are 200 scanning electrodes in the entire screen, only 40 of them are in the display state, and one scanning electrode is in the display state. This is an example of a case where a horizontal line is displayed everywhere.
[0102]
The length of one frame period is 200H. The cycle of the data latch signal LP is 1H, and one row of scan electrodes is sequentially selected for each clock of LP. The selection voltage VH or VL is applied to the scanning electrodes in the selected row, and the non-selection voltage VC is applied to the scanning electrodes in the other rows. Waveforms of Y1 to Y40 and Y41 to Y200 indicate scan voltage driving waveforms applied to the scan electrodes of rows 1 to 200. The scanning electrodes Y1 are sequentially selected at the first clock of the LP, Y2 at the second clock,...,... At the 40th clock, and the selection of the 40 rows goes round during 40H. While the 40 rows are selected, the partial display control signal PD keeps the “H” level. When the selection of the 40 rows is completed, the PD becomes the “L” level, and the remaining period 160H continues the “L” level. Normally, the Y driver 2 has a control terminal for asynchronously fixing all outputs to the non-selection voltage VC. By inputting the PD to such a control terminal of the Y driver 2, during the non-display row access period 160H in which the PD is in the "L" period, all the scanning electrodes are fixed at the non-selection level.
[0103]
Note that M is a liquid crystal AC drive signal, which switches the polarity of the drive voltage (the difference between the scan voltage and the signal voltage) applied to the liquid crystal of the pixel between the “H” level and the “L” level. Xn is applied to the nth signal electrode when only 1 to 40 rows are in a display state, 41 to 200 rows are in a non-display state, and a horizontal line is displayed every other scanning electrode in the display state. 3 shows a driving waveform of a signal electrode.
[0104]
FIG. 9 shows an example in which the polarity inversion of the liquid crystal drive voltage is inverted for each frame. The selection voltage applied to the scanning electrode is VH when the liquid crystal AC drive signal M is "L", and is VL when it is "H". When M is "L", the signal voltage is -VX for an ON pixel and VX for an OFF pixel. When M is "H", the signal voltage is VX for an ON pixel and -VX for an OFF pixel. As described in the previous embodiment, when the number of rows to be partially displayed is small and the non-display area is large, the signal electrodes and the scanning are performed during a relatively long non-display row access period after the display area is driven at a high duty. Although the potential of the electrode was fixed and the polarity was inverted every frame, as a result of the experiment, there was no problem in image quality. Further, since the liquid crystal driving voltage is fixed during the non-display access period, the power consumption due to the charge / discharge current and the through current generated by the voltage change in the liquid crystal layer, the Y driver 2 and the X driver 3, the controller 5, and the like. Is greatly reduced, which is also preferable in terms of low power consumption. The larger the non-display area, the longer the non-display access period and the longer the fixed period of the scanning voltage and the signal voltage, so that the charge and discharge of the liquid crystal and the circuit are suppressed and the power consumption can be further reduced.
[0105]
As the voltage applied to the signal electrode Xn during the non-display row access period, the voltage (VX in FIG. 9) when the scan electrode in the last row (Y40) of the display area is selected is continued. The signal voltage during the non-display row access period is fixed to a constant voltage in one frame, but is switched between VX and -VX for each frame. As described above, the signal voltage in the non-display row access period does not need to be the same in each frame. In this manner, when switching between the full screen display state and the partial display state, the signal voltage in the non-display row access period is symmetrical with respect to the non-selection voltage VC so that the contrast of the displayed area does not change. By alternately repeating the two potentials, the effective voltage applied to the liquid crystal in the display area can be fixed at the same voltage. In this embodiment, VX and -VX correspond to the signal electrode voltage in the case of full-off display or full-on display of the display. Therefore, as in the above-described embodiment, the signal electrode voltage is in the non-display row access period. Is fixed to the same level as in the case of full on display or full off display.
[0106]
Note that a circuit similar to that in FIG. 5 may be used to form the signals PD and LP. The timing chart in this case may be modified as follows in FIG. That is, CA is set to FRM, the length of fn is set to one frame period (200H), the number of LPI clocks in one frame period is set to 200, and the period when CNT is “H” is set to the 40th clock from the falling edge of the 200th LPI clock. Before the falling edge of LPI, the LP clock may be changed from the 1st LPI clock to the 40th clock, and the period during which the PD is “H” may be changed from the falling edge of the 1st LPI clock to the falling edge of the 41st clock.
[0107]
With the above method, the partial display function in the case of the SA driving method can be realized. Even by such a method, the power consumption in the partial display state can be reduced to a level almost proportional to the number of display rows.
[0108]
In the full screen display state, the control signal PD is always "H", LP is continuously supplied, and Y1 to Y200 are sequentially selected. In addition, in the full screen display state, it is necessary to invert the polarity of the liquid crystal drive voltage every predetermined period. For example, it is necessary to reverse the polarity by switching the polarity of the selection voltage and the signal voltage every 13H. In addition, the polarity of the liquid crystal drive electrode may be inverted every frame period, or in addition, the polarity may be inverted every predetermined period in the frame.
[0109]
The time and voltage for applying the selection voltage to each scanning electrode in the display area are the same in the case of full screen display and the case of partial display in only some rows. Therefore, there is no element that needs to be added to the drive voltage forming circuit for the partial display function, and the number of rows to be partially displayed can be set by software using a circuit as shown in FIG.
[0110]
(Fifth embodiment)
The present embodiment is characterized in that the timing of the liquid crystal AC drive signal M during the period when the selection voltage is applied to the display row is the same in the case of full screen display and the case of partial display in only some rows. This is an example of a case different from the fourth embodiment. The drive voltage generating circuit 4 as shown in FIG. 8, which mainly uses the SA drive method and the charge pump circuit, is employed. There are 200 scanning electrodes on the entire screen, and only 40 of them are in the display state. This is an example in which a horizontal line is displayed every other scan electrode in the display state, the length of one frame period is 200H, and the application to the scan electrodes during the non-display row access period The point that the voltage is fixed to the non-selection voltage VC and the voltage applied to the signal electrode is fixed to VX or −VX symmetrical to VC, and the selection voltage applied to the scanning electrode is the liquid crystal AC drive signal M = When "L", the voltage is VH, when M = "H", it is VL. When the signal voltage is M = "L", -VX for an ON pixel, VX for an OFF pixel, and M = "H". At this time, the point that VX is at the ON pixel and −VX is at the OFF pixel is the fourth real point. Is the same as the form. Therefore, the description of the same parts as in the fourth embodiment will be omitted.
[0111]
FIG. 10 is a timing chart according to the present embodiment, in which the polarity of the liquid crystal drive voltage is switched every 13H (selection period of the scanning electrodes in 13 rows). Thus, the cycle of the liquid crystal AC drive signal M becomes 26H. Since 200H is not divisible by 26H, the timing of the liquid crystal AC drive signal M shifts by 8H per frame with respect to the frame start signal FRM, and returns to the start timing of FIG.
[0112]
In order to form a signal M having a constant cycle in the partial display state, the frequency of the continuous clock signal LPI shown in FIGS. What is necessary is just to divide. Although not shown in the case of full-screen display, it is assumed that the polarity of the liquid crystal drive voltage is similarly switched every 13H. In this manner, the timing of inverting the polarity of the voltage applied to the liquid crystal in the part displayed in the partial display state can be made the same as in the full screen display state.
[0113]
By doing so, the image quality of the part displayed in the partial display state can be made the same as that in the full screen display state. When LP is used instead of the continuous clock signal LPI to form the liquid crystal AC drive signal M, flicker may occur in the partial display state due to the relationship between the polarity inversion cycle of the drive voltage and the number of partial display rows. The image quality may be degraded by applying a DC voltage.
[0114]
(Sixth embodiment)
FIG. 11 is an example of a partial block diagram of the signal electrode drive circuit (X driver 3) in FIG. It corresponds to the 4MLS driving method, and the number of output terminals for driving the liquid crystal is set to 160 as an example. Hereinafter, the configuration of FIG. 11 and the function of each block will be described.
[0115]
A block 25 is a RAM for storing display data. The number of bits (160 × 240 pixels) corresponding to a liquid crystal display panel of up to 240 rows in binary display (display of only ON / OFF without gradation display) is provided. It is configured. The block 22 is a circuit for generating a signal for precharging the RAM 25 according to the data latch signal LP. A block 23 is a row address generation circuit for designating which four rows of display data are to be read from the RAM 25. The addresses sequentially specified in accordance with the frame start signal FRM and the data latch signal LP are the scanning electrodes of the four rows that are simultaneously selected. , The addresses of the four rows are sequentially incremented so as to collectively output the display data of the pixels of four rows × 160 columns according to the LP.
[0116]
The four rows of display data specified by the row address generation circuit 23 are read from the RAM 25 and sent to the read display data control circuit of the block 26 constituted by an AND gate. While the partial display control signal PD is at the "H" level, the same contents as the display data are sent to the next block 27 via the block 26. However, while the PD is at the "L" level, the display data from the RAM is ignored. Then, the data (0) of all pixels off is sent to the block 27. Here, while the PD is at the “L” level, the block 26 may be changed so that data (1) indicating that all the pixels are turned on is input to the block 27.
[0117]
The block 24 is a circuit for generating a Com pattern as shown in FIG. 4A in accordance with the polarity of the frame, the field, and the liquid crystal drive voltage. The Com pattern is stored in a ROM or the like, and the Com pattern is stored in the ROM or the like. Addressed by the liquid crystal AC drive signal M or the like, a Com pattern (the pattern is inverted / non-inverted according to the level of M) corresponding to the polarity of the liquid crystal drive voltage is selectively output. A block 27 is an MLS decoder for the X driver for forming a drive voltage selection signal from the Com pattern and the display data of four rows via the block 26. The MLS decoder 27 outputs five drive voltage selection signals for 160 pixels for one pixel.
The drive voltage selection signal is a set of five signals indicating which voltage is selected from five voltages of VC, ± V1, and ± V2. Don is a display control signal for setting the entire screen to a non-display state. When Don is set to the “L” level, only the signal instructing the selection of VC among the five selection signals becomes active. When Don becomes the “H” level, a signal voltage determined according to the determinant in FIG. 4C is selected from among five voltages based on the display data and the Com pattern displayed on the pixels in four rows in the column direction.
[0118]
The block 28 is a level shifter for expanding the voltage amplitude of the drive voltage selection signal from the logic voltage (Vcc-GND) to the liquid crystal drive voltage level (V2-[-V2]). A block 29 is a voltage selector for actually selecting one voltage from five voltages of VC, ± V1, and ± V2, and is connected to five voltage supply lines by a drive voltage selection signal whose voltage amplitude level is amplified. One of the switches is closed, and the selected voltage is output to each of the signal electrodes X1 to X160. The above is the configuration of the block diagram in FIG. 11 and the function of each block.
[0119]
During the non-display row address period in the partial display state, if the clock of the LP signal is stopped and input to the LP terminal of the X driver 3 of the present embodiment as shown in FIG. The row address generation circuit of the block 23 can be stopped, that is, the read operation of the RAM 25 can be stopped. At this time, since the LP is not input to the row address generation circuit 23 and the address is not incremented, the RAM 25 continues to output the last four rows of display data of the display area.
[0120]
Therefore, when the block 26 is omitted, as in the first embodiment, the signal voltage during the non-display row access period is the same as that when the scan electrodes of the last four rows of the display area are selected. Will do. However, as shown in FIG. 11, the presence of the block 26 allows a signal PD which becomes “L” to be input to the PD terminal of the X driver 3 during the non-display row access period as shown in FIG. As described above, the signal voltage in the non-display row access period keeps the same voltage (V1 or -V1) as the signal voltage in the full screen off display or the full screen on display.
[0121]
2. Description of the Related Art A driver with a built-in RAM that stores data to be displayed on the entire screen is used because it is effective in reducing the power consumption of a liquid crystal display device. In addition, in the MLS driving method of the selection voltage equal distribution type described in the first embodiment, the configuration of the liquid crystal display device becomes easier by using a driver with a built-in RAM. For these reasons, a RAM built-in driver compatible with the MLS driving method has begun to be used in a liquid crystal display device aiming at both improvement in image quality and low power consumption. In such a liquid crystal display device, power consumption accompanying a precharge (refresh) operation when reading display data from a RAM occupies a considerable part of the total power consumption. Therefore, in order to pursue low power consumption by the partial display function, it is necessary to stop the read operation of the RAM during the non-display row access period using the X driver as in the present embodiment.
[0122]
In the above embodiment, the MLS driving method in the case of simultaneous selection of four lines has been described. However, the number of simultaneously selected lines is not limited to four, and may be two or seven. Although the case where the application of the selection voltage is uniformly distributed in one frame has been described, the present invention is also applicable to a case where the application of the selection voltage is not uniformly distributed (a case where the intra-frame selection period for one scan electrode is continuous). In FIG. 11, the V2 terminal and the VC terminal are independent of the logic unit power supply voltage terminals Vcc and GND, but may be independent. A liquid crystal display device capable of gradation display instead of binary display, in which the display data RAM has a storage capacity corresponding to the number of gradation bits, or switching between screens by incorporating display data RAM for a plurality of screens The present invention can be applied to a liquid crystal display device capable of performing display.
[0123]
(Seventh embodiment)
FIG. 12 is an example of a block diagram of the scan electrode drive circuit (Y driver 2) of the present invention in FIG. 1 and corresponds to the 4MLS drive method as in the sixth embodiment. The number of output terminals for driving the liquid crystal is 240 as an example. Hereinafter, the configuration of FIG. 12 and the function of each block will be described.
[0124]
The block 32 is a shift register that sequentially transfers the field start signal CA bit by bit using the data latch signal LP as a clock. It consists of 60 bits and designates which of the 240 rows to apply the selection voltage to. A block 30 is an initial setting signal generating circuit which sets the first bit of the shift register 32 to 1 at the falling timing of the data latch signal LP when the frame start signal FRM or the field start signal CA is at "H" level, A signal is generated for clearing the 59th bit to 0. The block 31 is a circuit for generating a Com pattern in accordance with the field and the polarity of the liquid crystal driving voltage, as in the case of the Com pattern generation circuit 24 in FIG. 11, and the Com pattern is stored in a ROM or the like. Addressed by the start signal CA, the liquid crystal AC drive signal M, and the like, a Com pattern corresponding to the polarity of the liquid crystal drive voltage is selectively output. The Com pattern generation circuit of the X driver 3 and the Y driver 2 may be used in common. A block 33 is an MLS decoder for a Y driver that forms three drive voltage selection signals from the 60-bit selected row information specified by the shift register 32 and the Com pattern. The MLS decoder 33 outputs three drive voltage selection signals for 240 rows per row. The drive voltage selection signal is a set of three signals indicating which voltage is selected from the three voltages VH, VC, and VL.
[0125]
Don is a display control signal for setting the entire screen to a non-display state. When Don is set to the “L” level, only the signal instructing the selection of VC among the three selection signals becomes active. When Don becomes the “H” level, the scanning signal voltage determined according to the matrix of FIG. 4A based on the selected row and the Com pattern is selected from the three voltages.
[0126]
The block 34 is a level shifter for expanding the voltage amplitude of the drive voltage selection signal from the logic voltage (Vcc-GND) to (VH-VL). The block 35 is a voltage selector for actually selecting one voltage from the three voltages VH, VC and VL. One of the switches connected to the three voltage supply lines is closed by the drive voltage selection signal having the amplified voltage amplitude level, and the selected voltage is output to each of the scan electrodes Y1 to Y240. The above is the configuration of the block diagram in FIG. 12 and the function of each block.
[0127]
In the non-display row address period in the partial display state, if the data latch signal LP whose clock is stopped as shown in FIG. 3 is input to the LP terminal of the Y driver 2 of the present embodiment, the operation of the shift register 32 during that period is stopped. Can be done. Although the power consumption of the Y driver 2 is relatively small, it is preferable to stop the operation of the shift register 32 during the non-display row address period in the partial display state pursuing low power consumption.
[0128]
The reason why the initialization signal generating circuit of the block 30 is provided is to prevent an abnormal display at the timing when the display is shifted from the partial display state to the full screen display state. If there is no block 30, in the partial display state, for example, when operated at the timing of FIG. 3 or FIG. 7, the "H" level is written to the shift register 32 every 10 bits. Even so, in the partial display state, there is no problem because the bits after 10 bits are ignored by the signal PD. However, when shifting from this state to the full screen display state, 4 lines every 40 lines, 200 lines in the full screen , The selection voltage is applied simultaneously to 20 rows, and an abnormal display occurs instantaneously. Instead of providing the block 30, an initial setting circuit for clearing the shift register 32 when the PD is "L" is added so that the bits in the shift register 32 are initialized when shifting from the partial display state to the full screen display state. The state may be set. As described above, the shift register 32 needs a means for initializing the shift register when shifting from the partial display state to the full screen display state.
[0129]
(Eighth embodiment)
FIG. 13 is an example of a circuit diagram of the contrast adjustment circuit 13 of the present invention in FIG. 2 or FIG. Here, RV is a variable resistor, Qb is a bipolar transistor, and Qn is an n-channel MOS transistor. The signal PDH input to the gate of Qn is a signal obtained by expanding the voltage amplitude of the signal PD from the logic voltage (Vcc-GND) to (Vcc-VEE) by the level shifter. The resistance value of the transistor Qn in the ON state is assumed to be negligibly small as compared with the resistance value of RV. In the figure, for example, -V2 is -3V, VEE is -15V, and VL is -10V.
[0130]
If there is no transistor Qn, it is basically the same as the conventional contrast adjusting circuit shown in FIG. In the full-screen display state, the PDH is always at the “H” level, that is, Qn is always on, and the presence of Qn can be ignored in terms of resistance value and functions similarly to the conventional contrast adjustment circuit. A voltage obtained by dividing the voltage between -V2 and VEE by the variable resistor is extracted and supplied to the base of Qb, and Qb supplies a voltage about 0.5 V higher than the voltage supplied to the base as VL from the emitter. By adjusting the variable resistance RV, a selection voltage VL that provides an optimum contrast can be obtained. The same applies to the period when the PDH is at the “H” level in the partial display state, that is, the period when the selection voltage is applied to the display row.
[0131]
During the period when the PDH is at the “L” level in the partial display state, that is, during the non-display row access period, Qn is turned off and the function of the contrast adjustment circuit 13 stops. During this period, the base and the collector of Qb have the same potential as -V2, and Qb is completely turned off. During this period, the charge pump circuit of the drive voltage forming circuit 4 is in an operation stop state, and the application of the selection voltage is also stopped, so that the current consumption of the VL system is 0. Is retained, so there is no problem. By stopping the contrast adjustment circuit 4 during the non-display row access period as described above, the power consumption by the contrast adjustment circuit during this period can be reduced to 0, and the power consumption of the liquid crystal display device can be reduced.
[0132]
In the above embodiment, an example in which the signal PDH obtained by level-shifting the PD is required is described. However, if the configuration of the drive voltage forming circuit is devised, the partial display control signal PD is directly used instead of the level-shifted signal PDH. It is also possible to stop the contrast adjustment circuit.
[0133]
As described above, according to the first to eighth embodiments, there is provided a highly versatile electro-optical device in which the number of rows and the position of the partial display can be set by software without complicating the drive voltage forming circuit. It is possible to do. Further, it is possible to provide an electro-optical device in which power consumption during partial display is significantly reduced.
[0134]
In each of the above embodiments, the signal voltage during the non-display row access period is fixed within one field or is fixed at a predetermined period shorter than one frame. If the voltage is fixed for at least a longer period than the driving period of the same polarity (half period of the polarity inversion driving period) in the polarity inversion driving period of the liquid crystal driving, power consumption can be reduced. In this case, during the non-display row access period, The inversion may be performed with the signal voltage at the time of full-screen ON display and OFF display according to the predetermined cycle.
For example, the polarity inversion of the liquid crystal drive in the full-screen display state is performed every 11H or 13H in the simple matrix type liquid crystal display device described in the above embodiment, so the polarity inversion drive cycle is 22H or 26H, which will be described later. In such an active matrix type liquid crystal display device, since the polarity is inverted every 1H or dot period (= 1H / the number of horizontal pixels), the polarity inversion driving cycle is 2H or 2 dot periods. The polarity inversion drive cycle of the liquid crystal drive in the non-display area in the partial display state is longer than the cycle in the full screen display state, and in the simple matrix type liquid crystal display device, the applied voltage is fixed for at least 11H or longer than 13H. In the active matrix type liquid crystal display device, if the applied voltage is fixed for at least 1H or a period longer than the dot period, the driving frequency is reduced and the power consumption is reduced.
[0135]
Although the first to eighth embodiments according to the above description have been described on the assumption that the liquid crystal display device is a simple matrix type, an electro-optical device such as an active type liquid crystal display device having a two-terminal non-linear element in a pixel. The present invention can also be applied to FIG. 22 is a diagram showing an equivalent circuit diagram of such an active matrix type liquid crystal display device 1, in which 112 indicates a scanning electrode, 113 indicates a signal electrode, 116 indicates a pixel, 3 indicates an X driver, and 2 indicates a Y driver. . Each pixel 116 includes a two-terminal nonlinear element 115 electrically connected in series between the scanning electrode 112 and the signal electrode 113 and a liquid crystal layer 114. The order of connection of the two-terminal nonlinear element 115 to the liquid crystal layer 114 may be opposite to that in the drawing, but in any case, the current characteristic has nonlinearity according to the applied voltage between the two terminals like a thin film diode. It is used as a switching element utilizing this. As a configuration of a liquid crystal display panel, a two-terminal non-linear element and a pixel electrode and one of a scanning or signal electrode are formed on one substrate, and a wide scanning or signal electrode is formed on the other substrate so as to overlap the pixel electrode. The other of the signal electrodes is formed, and a liquid crystal layer is sandwiched between a pair of substrates. Also in such an active matrix type liquid crystal display panel, partial display can be performed by the same driving method as in the above embodiments. In the case of an active matrix type liquid crystal display panel, since a driving method in which a switching element is arranged in each pixel to hold a voltage is used, when shifting from the full screen display state to the partial display state, as described later. Preferably, at the time of transition, the off-display voltage is written to the pixels in the non-display area before the transition to the partial display state.
[0136]
(Ninth embodiment)
The present embodiment realizes a display without a sense of discomfort in the partial display state. FIG. 14 is a view for explaining a partial display state in the liquid crystal display device of the present invention. Reference numeral 1 denotes a normally white liquid crystal display panel which can display pixels (dots) of, for example, 240 rows × 320 columns. If necessary, the entire screen can be set to the display state. During standby, a part of the entire screen (for example, only the upper 40 lines as shown in FIG. 14) is set to the display state (display area D), and the remaining area is set to the display area. It can be in a non-display state (non-display area). Since it is a normally white type, the non-display area is displayed in white.
[0137]
The configuration of the liquid crystal display panel is the same as that of the first to eighth embodiments. Liquid crystal is sandwiched between a pair of substrates, and an electrode for applying a voltage to a liquid crystal layer is provided on the inner surface of the substrate. A polarizing element is arranged on the side as required. The setting of the transmission axis of the polarizing element differs depending on the type of liquid crystal. However, as is well known, white light is displayed when the effective voltage applied to the liquid crystal is lower than the threshold voltage of the liquid crystal. The polarizing element is not limited to the polarizing plate, and may be any polarizing element such as a beam splitter that transmits light of a specific polarization axis. As the liquid crystal, various types such as a type in which liquid crystal molecules are twisted (TN type, STN type, etc.), a type in which homeotropic alignment is performed, a type in which vertical alignment is performed, and a memory type such as ferroelectric can be used. Further, a light-scattering type liquid crystal such as a polymer-dispersed liquid crystal may be used. In this case, the polarizing element is eliminated and the alignment of the liquid crystal molecules is set to be a normally white type. Further, when a contrast equal to or higher than that of a normally black liquid crystal display panel is required, a light shielding layer (a light shielding frame between openings of adjacent pixels) is provided between dots on one inner surface of a pair of substrates. ) May be provided.
[0138]
When the liquid crystal display panel 1 is of a reflection type, a structure in which a reflection plate is disposed outside one substrate or a reflection member such as a reflection electrode or a reflection layer is formed on the inner surface of one substrate. The orientation axis of the liquid crystal molecules and the transmission axis of the polarizing element may be set such that when the effective voltage applied to the liquid crystal is equal to or less than the off-voltage lower than the threshold voltage, the reflection member reflects the incident light. In the case of a liquid crystal display panel using STN liquid crystal, a retardation plate is often arranged between the liquid crystal display panel and the polarizing element. In this case, the transmission axis is set in consideration of the retardation plate. In the case of using the transflective type, a lighting device for illuminating the liquid crystal display panel is provided, and the liquid crystal display panel 1 is used as a transmissive type when the lighting device is turned on, and as a reflective type when the lighting device is not turned on. A variety of configurations for the transflective type are conceivable, but a semi-transmissive plate may be arranged outside one of the substrates, or light having a predetermined polarization axis component may be transmitted and light having a polarization axis component substantially orthogonal thereto may be transmitted. A method of arranging a reflective polarizer that reflects light, a method of forming an electrode formed on the inner surface of one substrate into a structure that semi-transmits light (for example, making a hole), and the like are conceivable.
[0139]
When the liquid crystal display panel 1 is colored, a color filter is formed on the inner surface of the substrate in the case of a reflection type or a transflective type, or in the case of a transflective type, three colors emitted by the lighting device are time-series. Switching is possible.
[0140]
When the liquid crystal display panel 1 is in the partial display state, an effective voltage equal to or lower than an off voltage set lower than the threshold voltage is applied to the liquid crystal in the non-display area. As described above, since the liquid crystal display panel 1 is of a normally white type, the non-display area becomes white as shown in the figure, and the display area D has an intermediate portion corresponding to the display content on a white display background. Since an image of gradation display or black display is displayed, a partial display screen without a sense of incongruity is obtained.
[0141]
The structure of the liquid crystal display panel 1 is, in addition to the above structure, an active matrix type liquid crystal display panel in which a two-terminal nonlinear element is arranged in a pixel as described in FIG. An active matrix liquid crystal display panel in which both a scanning electrode and a signal electrode are formed in a matrix on a substrate and a transistor is formed for each pixel may be used.
[0142]
A method for applying an effective voltage equal to or less than the off voltage to the liquid crystal in the non-display area will be described below.
[0143]
FIG. 15 shows a configuration example of a liquid crystal display device according to the present invention. Reference numeral 1 denotes a normally white liquid crystal display panel, in which a substrate on which a plurality of scanning electrodes are formed and a substrate on which a plurality of signal electrodes are formed are arranged to face each other at an interval of several μm. Such a liquid crystal is sealed, and an electric field according to display data is applied to the liquid crystal of pixels (dots) arranged in a matrix in accordance with the intersection of the scanning electrode and the signal electrode to form a display screen. As an example, dots of 240 rows × 320 columns can be displayed on the entire screen. For example, an area where 40 rows × 160 columns of a hatched portion D at the upper left are partially displayed, and the other areas are in a non-display state. Shall be. A selection voltage is applied to the scanning electrode during the selection period, and an on-voltage or an off-voltage (and an intermediate voltage as necessary) applied to a signal electrode intersecting the scanning electrode is applied to the liquid crystal at the intersection. The orientation state of the liquid crystal molecules at that portion changes depending on the applied on-voltage and off-voltage, thereby displaying an image. Note that a non-selection voltage is applied to the scan electrodes during the non-selection period.
[0144]
Next, a block 2 is a Y driver that selectively applies a selection voltage or a non-selection voltage to a plurality of scanning electrodes, and a block 3 is a signal voltage (an on-voltage or an off-voltage, and an intermediate voltage between them) corresponding to the display data Dn. Voltage) to the signal electrode.
The drive voltage forming circuit of the block 4 forms a plurality of voltage levels necessary for driving the liquid crystal, and supplies the plurality of voltage levels to the X driver 3 and the Y driver 2. Each driver selects a predetermined voltage level from the supplied voltage levels according to a timing signal and display data, and applies the selected voltage level to signal electrodes and scanning electrodes of the liquid crystal display panel 1. A block 5 is an LCD controller for forming timing signals CLY, FRM, CLX, LP, display data Dn, and a control signal PD necessary for these circuits, and is connected to a system bus of an electronic device including the present liquid crystal display device. ing. A block 6 is a power supply outside the liquid crystal display device and supplying power to the liquid crystal display device.
[0145]
The circuit blocks of the liquid crystal display panel in this embodiment are almost the same as those in the first to eighth embodiments. In particular, when the simple matrix type liquid crystal display panel is used, the circuit blocks in the first to eighth embodiments are used. Partial display can be performed by the same driving method as in the embodiment.
[0146]
In the following description of the driving method, a driving method for selecting a scanning electrode for each row as described with reference to FIGS. 9 and 10 will be used as an example. A plurality of lines may be simultaneously selected by the MLS driving method.
[0147]
FIG. 16 is an example of a timing chart in a partial display state of the liquid crystal display device of FIG. 15, and is directed to a simple matrix type liquid crystal display panel. Dn is display data transferred from the controller 5 to the X driver 3, and a period during which the display data is transferred is indicated by a shaded block. The display data Dn for one display row (scanning electrode) is transferred at high speed from the controller 5 to the X driver 3 in the shaded block. CLX is a transfer clock for controlling transfer of the display data Dn from the controller 5 to the X driver 3. The X driver 3 has a built-in shift register, operates the shift register in synchronization with the clock CLX, and temporarily captures display data Dn for one display row sequentially into the shift register and the latch circuit. If the X driver 3 is a driver having a built-in RAM as shown in FIG. 11, the display data Dn is stored in the RAM 25.
[0148]
Next, LP is a data latch signal for collectively latching one row of the display data Dn from the shift register or the latch circuit in the next-stage latch circuit of the X driver 3. The number attached to LP is the row (scanning line) number of the display data Dn taken into the latch circuit of the X driver 3. That is, the display data Dn is transferred from the controller 5 to the X driver 3 in advance in a selection period before outputting a signal voltage corresponding to the display data Dn. For example, the display data of the 40th row is latched at the 40th of the LP, and thus is transferred before that in accordance with the clock CLX. Based on the display data Dn latched by the latch circuit, the X driver 3 selects a voltage selected from a plurality of voltage levels (on-voltage and off-voltage, and intermediate voltage as necessary) supplied from the drive voltage forming circuit 4. The level is output to the signal electrode.
[0149]
Next, CLY is a scanning signal transfer clock for each scanning line selection period, and FRM is a screen scanning start signal for each frame period. The Y driver 2 has a built-in shift register, and the shift register receives the screen scanning start signal FRM and sequentially transfers the FRM according to the clock CLY. The Y driver 2 sequentially outputs a selection voltage (VS or MVS) to the scanning electrodes according to this transfer. The number given to CLY indicates the number of the scan electrode to which the selection voltage is applied. For example, when the 40th CLY is input, the Y driver 2 applies a selection voltage to the scan electrodes in the 40th row during one cycle of CLY. Here, PD is a partial display control signal for controlling the Y driver 2. While the control signal PD is at the “H” level, the selection voltage (VS or MVS) is sequentially output from the Y driver 2 to the scan electrodes. However, when the control signal PD is at the “L” level, the non-selection voltage ( VC) is output. Such control can be easily implemented by prohibiting the output of the selection voltage from the Y driver 2 according to the PD and providing a gate in the Y driver 2 for setting all outputs to the non-selection voltage.
[0150]
As an example, the scanning electrodes in the third row are Y3, the scanning electrodes in the 43rd row are Y43, the signal electrodes in the 80th column are X80, and the signal electrodes in the 240th column are X240. . Y43 and X240 are a scanning electrode and a signal electrode in the non-display area, respectively. Note that the pixels in the 80th column of the display area are all turned on for 40 rows. Here, VS and MVS are positive-side and negative-side selection voltages, respectively, and VX and MVX are positive-side and negative-side signal voltages, respectively. VS and MVS are symmetric to each other with VC as the central potential, and so are VX and MVX. MVX is applied to the signal electrodes of the ON pixels in the row to which the selection voltage VS is applied, and VX is applied to the signal electrodes of the OFF pixels. Further, VX is applied to the signal electrode of the ON pixel in the row to which the selection voltage MVS is applied, and MVX is applied to the signal electrode of the OFF pixel.
[0151]
The PD is at the “H” level during a period when 40 rows of the display area D are selected, and at the “L” level during other periods. While the PD is at the “H” level, the Y driver 2 generates a voltage VS (MVS) for sequentially selecting the first row to the 40th row one by one to drive the scan electrodes. The output of the VS and the MVS is switched for each scanning electrode in units of a plurality of scanning electrodes, and is driven by line inversion. The non-selection voltage VC is applied to the scanning electrodes other than the selected one row. While the PD is at the “L” level, all outputs of the Y driver 2 are at the non-selection voltage level. Since the effective voltage applied to the liquid crystal of the 41st to 240th rows to which no selection voltage is applied is considerably smaller than the effective voltage applied to the liquid crystal of the off pixel in the display area, the 41st to 240th rows are completely in a non-display state. It becomes. During the selection period of the non-display area, a non-selection voltage level is applied to the scanning electrodes. However, the signal electrodes are applied from the X driver 3 to a predetermined voltage level according to the PD or display data stored in the X driver 3. The applied voltage level continues to be applied. However, it is preferable that the signal voltage in the non-display row access period of the non-display area is applied while periodically inverting with reference to VC. For example, it is preferable to invert the polarity of the signal voltage every frame period, or to invert the polarity periodically in units of a shorter period longer than the selection period.
[0152]
In the present embodiment, as shown by Dn, CLX, and LP in the figure, the data transfer corresponding to the non-display row access period is the display data transfer to the X driver 3 from the first row to the 40th row. Only the display is performed, and the data transfer for the display on the 41st to 240th lines is not necessary, so the operation is stopped. Here, in the case of the matrix type liquid crystal display panel, it is necessary to transfer the display data of the next selected row while the X driver 3 outputs the signal voltage corresponding to the display of the selected row. Therefore, the data transfer period precedes the PD by one scanning line selection period.
[0153]
The data transfer for 320 dots in the first row includes display data transfer for the first half 160 dots and transfer of off display data for the second half 160 dots. The data transfer on the second to 40th lines is stopped because only the display data for the first half 160 dots is transferred, and the transfer of the off display data for the second half 160 dots is unnecessary. Since the X driver 3 has a built-in latch circuit (storage circuit) for storing one row of display data, the right half of the X driver 3 is transferred first even if there is no data transfer for 160 dots in the latter half. The right half of the X driver 3 continues to output the signal voltage for turning off the display. Thus, an effective voltage for turning off the display is applied to the liquid crystal of the right half screen in the upper 40 rows.
[0154]
In the above-described embodiment, in order to simplify the description, the line-sequential driving in which the scanning electrodes are sequentially selected row by row is adopted, and the polarity inversion cycle of the liquid crystal driving voltage is set with the central potential VC being a non-selection voltage. The description has been given of the driving method in which one frame period is set. However, as described in the above embodiments, a plurality of scanning electrodes such as two or four are simultaneously selected as a unit and sequentially selected for each unit, and the same scanning electrode is selected a plurality of times during one frame period. A so-called MLS drive method may be used.
[0155]
As described above, in order to apply an effective voltage equal to or less than the off voltage to the liquid crystal in the non-display area in the simple matrix type liquid crystal display device, the non-display state is required when the non-display area corresponds to some scanning electrodes. The non-selection voltage may be constantly applied to the scanning electrodes in the region to be set, and when the non-display region corresponds to some of the signal electrodes, the signal electrodes in the region to be set to the non-display state are turned off. A voltage may be constantly applied.
[0156]
(Tenth embodiment)
As described above, in the ninth embodiment, an active matrix liquid crystal display device can be used as the structure of the liquid crystal display panel 1 in addition to the above-described simple matrix structure. In the present embodiment, the same drive as that of the ninth embodiment is performed on the liquid crystal display panel 1 as an active matrix type liquid crystal panel.
[0157]
As the active matrix liquid crystal display panel, an active matrix liquid crystal display panel in which a switching element composed of a two-terminal non-linear element such as a thin film diode called an MIM is arranged in each pixel as described in FIG. 22 is used. it can. In this case, one of the scanning electrode 112 or the signal electrode 113, the element 115 connected thereto, and the pixel electrode connected to the element 115 are formed on the element substrate, and the other electrode is formed on the other opposing substrate. As a result, the two-terminal nonlinear element 115 and the liquid crystal layer 114 are electrically connected in series between the scanning electrode 112 and the signal electrode 113. As a driving method, a selection voltage as shown by Y3 in FIG. 16 is applied to the scanning electrode 112 to make the element 115 conductive, and the signal voltage output to the signal electrode 113 is written to the liquid crystal layer 114. When a non-selection voltage is applied to the scanning electrode 112, the resistance of the element 115 increases and the element becomes non-conductive, and the voltage applied to the liquid crystal layer 114 is held.
[0158]
Further, an active matrix liquid crystal display panel having transistors in pixels as shown in the equivalent circuit diagram in FIG. 23 may be used as the liquid crystal display panel 1. In this panel, both a plurality of scanning electrodes 112 and a plurality of signal electrodes 113 are formed in a matrix on one substrate (element substrate) of a pair of substrates constituting the panel. A switching element composed of a transistor 117 is formed for each pixel in the vicinity of the intersection with, and a pixel electrode connected to the switching element is formed for each pixel. A common electrode connected to the common potential 118 is arranged as necessary (the common electrode may be formed on the element substrate) on the other substrate arranged opposite to this substrate at a predetermined interval. You. In a liquid crystal layer sandwiched between a pair of substrates, a portion sandwiched between a pixel electrode and a common electrode is driven as a liquid crystal layer 114 of each pixel for each pixel. As is well known, the gate of the transistor 117 arranged for each pixel is connected to the scanning electrode 112, the source is connected to the signal electrode 113, and the drain is connected to the pixel electrode. The transistor 117 is turned on in accordance with the selection voltage applied in the selection period, and supplies a data signal to the pixel electrode through the turned-on transistor 117. When a non-selection voltage is applied to the scan electrode 112, the transistor 117 becomes non-conductive. A storage capacitor connected to the pixel electrode is connected to the element substrate as needed to store and hold the applied voltage. Note that the transistor 117 is a thin film transistor when the element substrate is an insulating substrate such as a glass substrate, and a MOS transistor when the element substrate is a semiconductor substrate.
[0159]
In such an active matrix type liquid crystal display device, a method of applying an effective voltage equal to or less than an off voltage to liquid crystal of a pixel located in a non-display area defined in a display screen is as follows.
[0160]
As shown in FIG. 17, in a transition period for switching from the full-screen display state to the partial display state, a voltage lower than the off-voltage is written to at least the liquid crystal of the pixels in the non-display area during at least one frame period (1F). To That is, a voltage lower than the off-state voltage is written to the pixel 116 that is to be in the non-display state in the first frame (period T in the drawing) after the transition to the partial display state. In this case, as shown in the figure, the partial control signal PD is set to the “H” level also during the non-display row access period of the non-display area in the first frame, and a selection voltage is applied to the scan electrode 112 in the non-display area to apply When the switching elements 115 and 117 of the pixel are turned on and a voltage equal to or lower than the liquid crystal off-voltage is applied from the X driver 3 to all the signal electrodes 113, a voltage lower than the off-voltage is written to the liquid crystal layer 114 of the pixel in the non-display area. Can be.
[0161]
When the liquid crystal is a memory liquid crystal, the control signal PD is switched to the “H” level only during the non-display row access period during the period T instead of scanning all the scan electrodes, and the scan electrodes in the non-display area are not scanned. Only the scanning electrode 112 corresponding to the non-display area is sequentially selected to turn on the switching element of the pixel, and a voltage lower than the off voltage is written only to the liquid crystal layer 114 of the pixel in the non-display area. You may do so. In this case, during the period T, a non-selection voltage is applied to the scan electrode 112 corresponding to the display area D, and the voltage of the liquid crystal layer of the pixel is not rewritten.
[0162]
In the second and subsequent frames, a non-selection voltage is constantly applied to the scanning electrodes 112 in the non-display area, and the switching elements 115 and 117 of the pixels in the non-display area are always in a non-conductive state, and the voltage applied to the pixel electrodes is changed. May be kept at a voltage equal to or lower than the off-voltage written to the pixel 116 in the first frame (period T) which is a transition period in which the pixel transitions to the partial display state. In an active matrix display panel, such a procedure is necessary because each pixel 116 continues to hold the voltage applied during the selection period by the storage capacitor.
[0163]
Further, as shown in FIG. 15, in a partial display state, a non-display area (a non-display area on the right side of the display area D in FIG. 15) is provided in the same row as the display area D, or a vertical direction (vertical direction) of the screen. In the case where only the non-display area is provided, even if the selection voltage is applied to the scanning electrode, a voltage equal to or lower than the off-voltage for turning off the signal is always applied to the signal electrode 113 in the area to be set to the non-display state. Good. Then, even if the switching elements 115 and 117 are turned on by the selection voltage applied to the scanning electrode 112, a voltage equal to or lower than the off voltage is continuously applied to the pixel electrode, and the pixel electrode becomes a non-display area.
[0164]
The above-described method of applying an effective voltage equal to or less than the off-voltage to the liquid crystal of the pixel located in the non-display area can be realized by simple circuit means. When the partial display area D is formed in the vertical direction (vertical direction) of the screen, many parts of the controller 5, the drive voltage forming circuit 4, the X driver 3, and the Y driver 2 are not displayed in the partial display state. The power can be stopped during the row access period, and when the display is of the normally white type, a low voltage is applied to the pixels in the non-display area in the off display, so that the power consumption of the driving circuit is significantly reduced. Can be.
[0165]
In the case of a normally white liquid crystal, liquid crystal molecules are horizontally aligned in a non-display region in a horizontally aligned liquid crystal or the like. Since the liquid crystal molecules have a small dielectric constant in the horizontal alignment state, the charge / discharge current of the liquid crystal in the non-display area is also small, and the power consumption of the entire display device can be significantly reduced compared to the case of the full screen display state. it can.
[0166]
As described above, according to the ninth and tenth embodiments, the reflection type or the partial display state in which only a part of the entire screen is in the display state and the other areas are in the non-display state is possible. In the transflective liquid crystal display device, it is possible to realize a display without a sense of incongruity in the case of a partial display state, and to significantly reduce power consumption.
[0167]
The first to tenth embodiments can be applied not only to the liquid crystal display device but also to other electro-optical devices in which pixels are formed by arranging scanning electrodes and signal electrodes in a matrix. . For example, the present invention can be applied to a plasma display panel (PDP), electroluminescence (EL), field emission device (FED), and the like.
[0168]
(Embodiment of electronic device)
FIG. 24 is a diagram showing the appearance of an electronic device according to the present invention. A portable information device 221 has a built-in mobile phone function and is powered by a battery. Reference numeral 221 denotes a display device using the matrix-type electro-optical device or the liquid crystal display device according to any of the embodiments described above. The display device 221 enters a full-screen display state as shown in FIG. In such a standby state, only the display area of 221D which is a part of the display device 221 is partially displayed. Reference numeral 230 denotes a pen serving as an input unit. Since a touch panel is disposed on the front of the display device 221, a switch input can be performed by pressing the display portion with the pen 230 while viewing the screen of the display device 221.
[0169]
FIG. 25 is an example of a partial circuit block diagram of an electronic device of the present invention. 222 is a μPU (microprocessor unit) for controlling the entire electronic device, 223 is a memory for storing various programs, information, display data, and the like, and 224 is a crystal unit serving as a time standard source. The μPU 222 generates an operation clock signal in the electronic device 220 by the crystal oscillator 224 and supplies it to each circuit block. These circuit blocks are interconnected via a system bus 225, and are also connected to other blocks such as input / output devices. Power is supplied to these circuit blocks from a battery power supply 6. The display device 221 includes, for example, the liquid crystal display panel 1, the Y driver 2, the X driver 3, the drive voltage generation circuit 4, and the controller 5 as shown in FIG. The function of the controller 5 may be shared by the μPU 222.
[0170]
Here, by using the electro-optical device or the liquid crystal display device according to the above-described embodiment as the display device 221, the power consumption during standby of the entire electronic device is reduced, and the screen in the partial display state has fun and originality. Can be made.
[0171]
Furthermore, when the display device is a reflective display device, or when the display device has a light source for backlight illumination, but the light source is not used, the display device is a reflective display. It is preferable to use a semi-transmissive display device because the power consumption can be further reduced and the battery life can be extended. Furthermore, in the electronic device of the present invention, when the device is not operated and in a standby state after a lapse of a certain period of time, the display device is in a partial display state, so that power consumption due to driving of the display device by a driver or a controller is suppressed. The battery life can be further extended.
[0172]
(Industrial applicability)
An object of the present invention is to reduce power consumption of an electronic device such as a mobile phone by setting a mode of a display device in a standby state to a partial display state in which only a necessary portion is displayed, in an electronic device having a long standby time. Can be done.
[Brief description of the drawings]
FIG. 1 is a block diagram of a liquid crystal display device according to an embodiment of the present invention.
FIG. 2 is a block diagram of a drive voltage forming circuit used in the embodiment of the present invention.
FIG. 3 is a timing chart according to the embodiment of the present invention.
4A and 4B are diagrams for explaining a liquid crystal driving voltage waveform in the embodiment of the present invention, where A is a diagram showing a selection voltage VS field (Com pattern), b is a diagram showing a display pattern, and C is a signal electrode. It is a figure showing a drive voltage VS display pattern.
In FIG. 7A, Y4n + 1 to Y4n + 4 mean the selected first to fourth rows (n = 0, 1, 2,..., 49). 1 means VH and -1 means VL. The matrix of A is when the liquid crystal AC drive signal M is "L", and when M is "H", ± is reversed. In B in the figure, d1 to d4 indicate the on / off states of the pixels on the selected first to fourth rows. An ON pixel is represented by -1 and an OFF pixel is represented by 1. In C in the figure, 0 means VC, ± 2 means ± V1, and ± 4 means ± V2 in the calculation results. The matrix of C is when the liquid crystal AC drive signal M is “L”, and when M is “H”, ± is reversed.
FIG. 5 is a partial view of a control circuit according to the embodiment of the present invention.
FIG. 6 is a timing chart showing the operation of the circuit of FIG. 5;
FIG. 7 is a timing chart according to another embodiment of the present invention.
FIG. 8 is a block diagram of a liquid crystal drive voltage forming circuit used in another embodiment of the present invention.
FIG. 9 is a timing chart according to another embodiment of the present invention.
FIG. 10 is a timing chart according to another embodiment of the present invention.
FIG. 11 is a partial block diagram of a signal electrode drive circuit according to the embodiment of the present invention.
FIG. 12 is a block diagram of a scan electrode driving circuit according to the embodiment of the present invention.
FIG. 13 is a circuit diagram of a contrast adjustment circuit according to the embodiment of the present invention.
FIG. 14 is a diagram illustrating a partial display state in the liquid crystal display device of the present invention.
FIG. 15 is a diagram showing a configuration example of a liquid crystal display device of the present invention.
FIG. 16 is a timing chart showing the operation of the liquid crystal display device of FIG.
FIG. 17 is a view for explaining a transition from a full screen display state to a partial display state in the liquid crystal display device of FIG. 15;
FIG. 18 is a diagram illustrating a partial display state in a conventional liquid crystal display device.
FIG. 19 is a block diagram of a conventional liquid crystal display device having a partial display function.
20 is a drive voltage waveform diagram of the liquid crystal display device of FIG.
FIG. 21 is a detailed circuit diagram of a drive voltage generation circuit in FIG. 19;
FIG. 22 is an equivalent circuit diagram of a pixel of an active matrix liquid crystal display panel having a two-terminal nonlinear element in the pixel.
FIG. 23 is an equivalent circuit diagram of a pixel in an active matrix liquid crystal display panel including a transistor in the pixel.
FIG. 24 is a schematic view of an electronic apparatus using the electro-optical device or the liquid crystal display device of the invention as a display device.
FIG. 25 is a circuit block diagram of an electronic device of the invention.
[Explanation of symbols]
1,51… liquid crystal display panel
2,52 ... scan electrode drive circuit (Y driver)
3,53 ... signal electrode drive circuit (X driver)
4,54… Liquid crystal drive voltage forming circuit
5,55… LCD controller
6,56… Power supply
7, 17… Step-up / step-down clock forming circuit
8 Negative direction 6 times booster circuit
9,20 ... double booster circuit
10 Negative double booster circuit
11, 12, 19 ... 1/2 step-down circuit
13, 21… contrast adjustment circuit
14… Register
15: Partial display control signal forming unit
16… AND gate
18 Negative direction 8 times booster circuit
22 ... Precharge signal generation circuit
23… row address generation circuit
24, 31 ... Com pattern generation circuit
25 ... display data RAM
26 ... Readout display data control circuit
27 ... MLS decoder for X driver
28, 34… Level shifter
29, 35… voltage selector
30: Initial setting signal generation circuit
32… shift register
33 MLS decoder for Y driver
57… Scan control circuit
107 ... Normally black liquid crystal display panel
FRM ... Frame start signal (screen scanning start signal)
CA: Field start signal
CLY: Scan signal transfer clock
CLX: Data transfer clock
Data, Dn ... Display data
LP, LPI ... data latch signal
PD, CNT, PDH ... Partial display control signal
Don ... display control signal
Vcc: Input power supply voltage
GND: ground potential
VEE: Negative high voltage
VH… positive selection voltage
VL… negative selection voltage
VC: Non-selection voltage (center potential)
± V1, ± V2, ± VX (, VC) ... signal voltage
V0 to V5: liquid crystal drive voltage
f1 to f4 ... Field classification symbol
M: LCD AC drive signal
Xn ... signal electrode
Y1 to Y200, Y4n + 1 to Y4n + 4 ... scanning electrodes
RV, RV1 ... variable resistance
Qb, Q1 ... bipolar transistor
Qn: n-channel MOS transistor
R1, R2, R3a, R3b, R4, R5 ... resistance
S2a, S2b ... switch
OP1 to OP4 ... Operational amplifier
D: Partial display area
VS… positive selection voltage
MVS: Negative selection voltage
VX: Positive signal voltage
MVX… negative signal voltage

Claims (33)

In a driving method of an electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect and have a function of partially setting a display screen as a display area,
To the scan electrodes in the display area, a selection voltage is applied during a selection period and a non-selection voltage is applied during a non-selection period. By fixing the applied voltage of at least and fixing the applied voltage to all the signal electrodes for at least a predetermined period,
A method for driving an electro-optical device, wherein the display screen is set to a partial display state. 2. The method of driving an electro-optical device according to claim 1, wherein a voltage of the scanning electrode during a period in which the voltage applied to all the scanning electrodes is fixed is the non-selection voltage. 3. The method according to claim 2, wherein the non-selection voltage is at one level. 4. The circuit according to claim 1, wherein the driving voltage forming circuit applied to the scanning electrodes and the signal electrodes is configured to fix the applied voltages to all the scanning electrodes and all the signal electrodes. 5. And a method of driving the electro-optical device, wherein the operation is stopped. 5. The drive voltage forming circuit according to claim 4, further comprising a charge pump circuit that switches a connection of the plurality of capacitors according to a clock to generate a boosted voltage or a stepped-down voltage. The method of driving an electro-optical device, wherein the operation is stopped during a period in which the applied voltages to the electrodes and all the signal electrodes are fixed. 6. The first display mode according to claim 1, wherein the entire display screen is in a display state, a partial area of the display screen is in a display state, and other areas are in a non-display state. A second display mode, wherein a time for applying a selection voltage to each scan electrode in the display area is not changed between the first display mode and the second display mode. Driving method of optical device. 7. The display area according to claim 6, wherein an effective voltage applied to a liquid crystal of a pixel in the display area in a display state is the same in the first display mode and the second display mode. And setting a potential to be applied to the signal electrode during a period other than the scanning electrode selection period. 8. The potential according to claim 7, wherein a potential applied to the signal electrode during a period other than a selection period of a scanning electrode in the display area is a voltage applied to the signal electrode in an on-display or an off-display in the first display mode. A driving method for the electro-optical device, wherein 9. The device according to claim 8, wherein the plurality of scan electrodes are driven so as to simultaneously select every predetermined number of units and sequentially select every predetermined number of units.
The voltage applied to the signal electrode in the case of ON display or OFF display in the second display mode is applied to the signal electrode in the case of full screen ON display or full screen OFF display in the first display mode. A method for driving an electro-optical device, wherein the driving voltage is the same as the voltage. 10. The potential according to claim 1, wherein the potential applied to the signal electrode during a period other than the selection period of the scan electrode in the display area is turned on in the full-screen display state for each predetermined period of one screen scan. A method for driving an electro-optical device, wherein an applied potential for displaying and an applied potential for off-display are alternately switched and set. 11. The polarity of the voltage difference between the scan electrode and the signal electrode in each of frames other than the selection period of the scan electrode in the display area in the second display mode according to any one of claims 6 to 10. A method for driving an electro-optical device, comprising: In a driving method of an electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect and have a function of partially setting a display screen as a display area,
To the scan electrodes in the display area, a selection voltage is applied during a selection period and a non-selection voltage is applied during a non-selection period, and the scan electrodes in other areas of the display screen are not applied with the selection voltage. The non-selection voltage is applied to all the signal electrodes, and the applied voltage is fixed for at least a period longer than the same polarity drive period in the polarity inversion drive in the full screen display state, thereby changing the display screen. A method for driving an electro-optical device, wherein a partial display state is set. The voltage applied to the signal electrode according to claim 12, wherein the voltage applied to the signal electrode is at least every period longer than the same polarity driving period in the polarity inversion driving in the full-screen display state, and the potential when turning on the display in the full-screen display state. A method for driving an electro-optical device, wherein the potential is alternately switched to a potential when an off display is performed. 14. The driving method of an electro-optical device according to claim 1, wherein the electro-optical device is a simple matrix type liquid crystal display device. 14. The driving method of an electro-optical device according to claim 1, wherein the electro-optical device is an active matrix liquid crystal display device. An electro-optical device driven by the method for driving an electro-optical device according to claim 1. In an electro-optical device having a configuration in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect and have a function of partially setting a display screen as a display area, a selection voltage is applied to the plurality of scanning electrodes during a selection period. A scan electrode driving circuit for applying a non-selection voltage during a non-selection period;
A signal electrode drive circuit for applying a signal voltage according to display data to the plurality of signal electrodes;
Setting means for setting position information of a partial display area in the display screen;
Control means for outputting a partial display control signal for controlling the scan electrode drive circuit and the signal electrode drive circuit based on the position information set in the setting means, the scan electrode drive circuit and the signal The electrode drive circuit drives the scan electrodes and the signal electrodes in a display area in a display screen to display according to display data in accordance with the partial display control signal, and controls a non-display area in the display screen. An electro-optical device, wherein a non-display state is maintained by continuously applying a non-selection voltage to the scanning electrode. The electro-optical device according to claim 17, wherein the electro-optical device is a simple matrix liquid crystal display device. The electro-optical device according to claim 17, wherein the electro-optical device is an active matrix liquid crystal display device. A plurality of scanning electrodes and a plurality of signal electrodes are arranged so as to intersect, in a drive circuit of an electro-optical device having a function of partially using a display screen as a display area,
First driving means for applying a voltage to the plurality of scanning electrodes; and a storage circuit for display data, wherein a voltage selected according to the display data read from the first electrode is applied to the plurality of signal electrodes. And second driving means for
The first driving unit applies a selection voltage to a scan electrode in the display area during a selection period and applies a non-selection voltage to a scan electrode in a non-selection period, and applies a non-selection voltage to a scan electrode in another area of the display screen. Having a function of applying only the non-selection voltage,
A second driver for reading display data from the storage circuit during a period corresponding to a selection period of a scan electrode in the display region, and fixing a display data read address of the storage circuit during other periods; A driving circuit for an electro-optical device, comprising: 21. The driving circuit for an electro-optical device according to claim 20, wherein a shift operation of a shift register in the first driving unit is stopped during a period other than a selection period of a scanning electrode in the display area. A plurality of scanning electrodes and a plurality of signal electrodes are arranged so as to intersect, in a drive circuit of an electro-optical device having a function of partially using a display screen as a display area,
A scan electrode drive circuit for sequentially applying a selection voltage to the plurality of scan electrodes in accordance with a shift operation of the shift register;
The scan electrode drive circuit applies a selection voltage to a scan electrode in a display area of the display screen during a selection period in accordance with a shift operation of the shift register when a display screen is partially used as a display area. The shift operation of the shift register is stopped halfway on the scan electrodes in other areas of the display screen, and only the non-selection voltage is applied. The scan electrode drive circuit partially controls the display screen. A drive circuit for the electro-optical device, further comprising an initial setting unit for setting the shift register to an initial state when the display area shifts from a display area state to a full screen display state. An electro-optical device comprising: a driving circuit of the electro-optical device according to claim 20; and a scanning electrode and a signal electrode driven by the driving circuit. In an electro-optical device having a function in which a plurality of scanning electrodes and a plurality of signal electrodes are arranged to intersect and have a function of partially setting a display screen as a display area, first driving means for applying a voltage to the plurality of scanning electrodes And a second drive unit including a display data storage circuit and applying a voltage selected according to the display data read from the display data to the plurality of signal electrodes,
The first driving means applies a selection voltage during a selection period and a non-selection voltage during a non-selection period to a scan electrode in a display area of the display screen, and applies a non-selection voltage to another area of the display screen. The scanning electrode has a function of applying only the non-selection voltage,
The second driving means applies a voltage to the plurality of signal electrodes based on display data read from the storage circuit during a selection period of the scan electrode in the display area, and applies the same voltage during other periods. An electro-optical device having a function of applying a voltage based on the display data. 25. The device according to claim 24, wherein, during a period other than the selection period of the scanning electrodes in the display area, the second driving unit is provided at least every period longer than the same polarity driving period in the polarity inversion driving in the full screen display state. An electro-optical device, wherein a voltage applied to the signal electrode is alternately switched between a potential for ON display and a potential for OFF display in a full screen display state. 26. The driving voltage forming circuit according to claim 23, further comprising a driving voltage forming circuit that forms a voltage applied to the scanning electrode or the signal electrode and supplies the voltage to the driving unit. Including a contrast adjustment circuit that adjusts the voltage of the voltage,
An electro-optical device, wherein the operation of the contrast adjustment circuit is stopped during a period other than the selection period of the scanning electrode in the display area. In a driving method of a reflective or semi-transmissive liquid crystal display device capable of a partial display state in which a partial area of the entire screen of the liquid crystal display panel is displayed and a non-display state is set in another area,
A method of driving a liquid crystal display device, wherein the liquid crystal display panel is of a normally white type, and an effective voltage equal to or less than an off voltage is applied to the liquid crystal in the non-display area in the partial display state. 28. The method according to claim 27, wherein the liquid crystal display panel is a simple matrix liquid crystal panel, and applies only a non-selection voltage to the scanning electrodes in the non-display area in the partial display state. . 29. The liquid crystal display according to claim 27, wherein the liquid crystal display panel is a simple matrix type liquid crystal panel, and in the partial display state, only a voltage that turns off the signal electrode in the non-display area is applied. How to drive the device. 29. The liquid crystal display panel according to claim 27, wherein the liquid crystal display panel is an active matrix type liquid crystal panel, and applies a voltage equal to or less than an off voltage to liquid crystals of the pixels in the non-display area in at least the first frame in which the display mode shifts to the partial display state. A method of driving a liquid crystal display device, wherein only a non-selection voltage is applied to a scan electrode in the non-display area from a subsequent frame. 31. The liquid crystal display panel according to claim 27, wherein the liquid crystal display panel is an active matrix liquid crystal panel, and a voltage equal to or less than an off voltage is applied to the liquid crystal of the pixels in the non-display area in at least the first frame when the partial display state is entered. A driving method for a liquid crystal display device, wherein only a voltage lower than an off voltage is applied to the signal electrode during an access period of the non-display area from a subsequent frame. A liquid crystal display device which is displayed by the method for driving a liquid crystal display device according to any one of claims 27 to 31. An electronic apparatus using the electro-optical device or the liquid crystal display device according to any one of claims 16 to 19, 23 to 26, and 32 as a display device.

Images