1. Field of the Invention
The present invention relates to a display drive device, a drive control method of the same, and a display apparatus having the same, and particularly relates to a display drive device suitably applicable to a display panel conforming to an active-matrix type drive system, a drive control method of the same, and a display apparatus having the same.
2. Description of the Related Art
In recent years, a liquid crystal display (LCD) has been frequently used as a display apparatus (display) for displaying image and character information, etc. in imaging apparatuses such as widely-spreading digital video cameras and digital still cameras, and in portable apparatuses such as cellular phones and personal digital assistants (PDA). Further, a liquid crystal display is widely used as a monitor or display apparatus for information terminals such as computers and for visual equipment such as television sets. A liquid crystal display used for such purposes is thin-shaped, light-weighted, adaptable to low power consumption, and excellent in display quality.
A liquid crystal display according to prior art will now be briefly described.
As illustrated in
As shown in
The scanning lines SL and the data lines DL arranged in the liquid crystal display panel 110P are connected via connection terminals TMg and TMs to the gate driver 120P and the source driver 130P which are provided independently from the liquid crystal display panel 110P. An electrode (compensating electrode) at the other end of the compensating capacitor Cs receives application of a predetermined voltage Vcs (for example, a common signal voltage Vcom) via a common connection lines CL.
In the liquid crystal display 100P having the above-described configuration, display data supplied from the display signal generation circuit 160P and corresponding to display pixels in one row of the liquid crystal display panel 110P are sequentially acquired by the source driver 130P based on a horizontal control signal supplied from the LCD controller 150P. In the meantime, based on a vertical control signal supplied from the LCD controller 150P, the gate driver 120P sequentially applies a scanning signal to the scanning line SL arranged in the liquid crystal display panel 110P. As a result, the pixel transistors TFT of the group of display pixels Px in each row are turned on and set to the selected state in which each pixel can acquire a display signal voltage. In synchronization with the timing the group of display pixels Px in each row are selected, the source driver 130 supplies a display signal voltage based on the acquired display data simultaneously to the display pixels Px via the data lines DL.
As a result, via the pixel transistor TFT of each display pixel Px set to the selected state, the liquid crystal molecules sealed in the pixel capacitor Clc change their orientation state in accordance with the display signal voltage and perform a predetermined gradational display operation, and the compensating capacitor Cs connected in parallel to the pixel capacitor Clc is charged with the voltage applied to the pixel capacitor Clc. By this series of operations being repeated for the rows included in one screen, desired image information based on a video signal is displayed on the liquid crystal display panel 110P.
As shown in
However, the liquid crystal display as described above has the following problems.
That is, according to the structure shown in
Moreover, as the number of output terminals of the gate driver 120P and source driver 130P is increased, the number of connection terminals for connecting the liquid crystal display panel 110P and each driver is increased and the pitch between the connection terminals becomes small. Therefore, the number of steps required in connection process is increased and a higher connection precision is required, leading to a problem that the production cost is raised.
As a technique for solving the problem regarding the number of steps required for connecting the liquid crystal display panel and peripheral circuits and the problem of connection precision, there is known a structure in which a liquid crystal display panel, a gate driver, and a source driver are integrally formed on a single insulating substrate, with the use of polysilicon transistors. However, unlike transistor devices such as an amorphous silicon transistor, for which a production technique has been established and from which a good device property (operation property) can be obtained, a polysilicon transistor has to go through a complicated production process that costs high, and its operation property is insufficient. Therefore, there has been a problem that the production cost required for a liquid crystal display apparatus becomes higher and a stable display characteristic is hard to obtain.
The present invention relating to a display drive device for driving, based on display data, a display panel on which display pixels are arranged adjacent to intersections of a plurality of signal lines and a plurality of scanning lines and a display apparatus having the same has an advantage of being able to downsize the display drive device, reduce the power to be consumed, and obtain a good display quality.
A display drive device according to a first aspect of the present invention for acquiring the above-stated advantage comprises: a first data conversion circuit which converts each predetermined number of display data into pixel data in which the respective display data are arranged in time-series and in a predetermined arranging order; a display signal voltage generation circuit which generates display signal voltages which correspond to the pixel data and are to be applied to display pixels via a plurality of signal lines; a second data conversion circuit which is provided for each the predetermined number of signal lines of the plurality of signal lines, converts the display signal voltages so as to correspond to the arranging order of the display data in the pixel data, and sequentially applies the display signal voltages to the predetermined number of signal lines respectively; and a control section which changes an order of applying the display signal voltages to the signal lines, at a predetermined cycle.
The display drive device further comprises a data holding circuit which acquires the display data which are supplied from outside, and holds the display data in parallel with one another, and the first data conversion circuit converts the display data held by the data holding circuit into the pixel data.
The control section changes the arranging order of the display data in the pixel data at the predetermined cycle.
The control section reverses the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, per field period in which a display operation for one screen of a display panel is performed or per horizontal period in which a display operation for one row of a display panel is performed. Further, the control section sets the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, in a manner that, with a predetermined plural number of field periods set as one cycle, fluctuations in pixel potentials stored in the display pixels based on the display signal voltages applied via the signal lines are canceled in the predetermined plural number of field periods.
The second data conversion circuit includes a plurality of switches which apply the display signal voltages to the predetermined number of signal lines respectively, and the control section includes a switch drive control circuit which generates, based on a timing signal, switch toggling signals for controlling electrical conductivity of the plurality of switches in the second data conversion circuit.
A display drive device according to a second aspect of the present invention for acquiring the above-stated advantage comprises a first data conversion circuit which converts each predetermined number of display data into pixel data in which the respective display data are arranged in time-series; a display signal voltage generation circuit which generates display signal voltages which correspond to the pixel data and are to be applied to display pixels via a plurality of signal lines; a second data conversion circuit which is provided for each the predetermined number of signal lines of the plurality of signal lines, converts the display signal voltages so as to correspond to an arranging order of the display data in the pixel data, and sequentially applies the display signal voltages to the predetermined number of signal lines in writing periods which are set variedly for the respective signal lines; and a control section which sets the writing periods for the respective signal lines, to periods corresponding to writing speeds at the display pixels.
The control section sets the waiting period for the signal line to which the display signal voltage is applied at a last timing among the predetermined number of signal lines, to a period which continues until writing of the display signal voltages in the display pixels is completed.
A display apparatus according to a third aspect of the present invention for acquiring the above-stated advantage comprises a scanning drive circuit which sequentially applies scanning signals to a plurality of scanning lines to set display pixels to a selected state; a data holding circuit which acquires display data which is supplied from outside, and holds the display data in parallel with one another; a first data conversion circuit which converts each predetermined number of the display data held by the data holding circuit, into pixel data in which the respective display data are arranged in a predetermined arranging order and in time-series; a display signal voltage generation circuit which generates display signal voltages which correspond to the pixel data and are to be applied to display pixels via the plurality of signal lines; a second data conversion circuit which is provided for each the predetermined number of signal lines of the plurality of signal lines, converts the display signal voltage so as to correspond to the arranging order of the display data in the pixel data, and sequentially applies the display signal voltages to the predetermined number of signal lines respectively; and a control section which changes the arranging order of the display data in the pixel data and an order of applying the display signal voltages to the signal lines, at a predetermined cycle. The second data conversion circuit is integrally formed on a single insulating substrate on which a display panel is formed.
The control section reverses the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, per field period in which a display operation for one screen of the display panel is performed or per horizontal period in which a display operation for one row of the display panel.
The control section set the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, in a manner that, with a predetermined plural number of field periods set as one cycle, fluctuations in pixel potentials stored in the display pixels based on the display signal voltages applied via the signal lines are canceled in the predetermined plural number of field periods.
The second data conversion circuit includes a plurality of switches which apply the display signal voltages to the predetermined number of signal lines respectively, and the control section includes a switch drive control circuit which generates, based on a timing signal, switch toggling signals for controlling electrical conductivity of the plurality of switches in the second data conversion circuit. The switch drive control circuit is, for example, formed integrally with the scanning drive circuit.
Each of the plurality of display pixels includes a pixel transistor whose gate electrode is connected to the scanning line, whose drain electrode is connected to the signal line, and whose source electrode is connected to a pixel electrode, a pixel capacitor which is formed of liquid crystal molecules sealed between the pixel electrode and a common electrode opposing to the pixel electrode and provided in common, and a compensating capacitor connected in parallel to the pixel capacitor, and orientation state of the liquid crystal molecules of the pixel capacitor is controlled by the display signal voltage being applied to the pixel electrode via the pixel transistor.
A display apparatus according to a fourth aspect of the present invention for acquiring the above-stated advantage comprises: a scanning drive circuit which sequentially applies scanning signals to a plurality of scanning lines to set display pixels to a selected state; a data holding circuit which acquires display data which are supplied from outside, and holds the display data in parallel with one another; a first data conversion circuit which converts each predetermined number of the display data held by the data holding circuit, into pixel data in which the respective display data are arranged in a predetermined arranging order and in time-series; a display signal voltage generation circuit which generates display signal voltages which correspond to the pixel data and are to be applied to display pixels via a plurality of signal lines; a second data conversion circuit which is provided for each the predetermined number of signal lines of the plurality of signal lines, converts the display signal voltages so as to correspond to the arranging order of the display data in the pixel data, and sequentially applies the display signal voltages to the predetermined number of signal lines respectively in writing periods which are set variedly for the respective signal lines; and a control section which sets the writing periods for the respective signal lines, to periods corresponding to writing speeds at the display pixels.
The control section sets the writing period for the signal line to which the display signal voltage is applied at a last timing among the predetermined number of signal lines, to a period which continues until writing of the display signal voltages in the display pixels is completed.
A drive control method of a display drive device according to a fifth aspect of the present invention for acquiring the above-stated advantage comprises: acquiring display data and holding the display data in parallel with one another; converting each predetermined number of the held display data, into pixel data in which the respective display data are arranged in a predetermined arranging order and in time-series; generating display signal voltages which correspond to the pixel data; sequentially applying the display signal voltages to each the predetermined number of signal lines of a plurality of signal lines, in an order corresponding to the arranging order of the display data in the pixel data; and changing the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, at a predetermined cycle.
The changing of the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines reverses the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, per field period in which a display operation for one screen of a display panel is performed or per horizontal period in which a display operation for one row of a display panel is performed.
The changing of the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines sets the arranging order of the display data in the pixel data and the order of applying the display signal voltages to the signal lines, in a manner that, with a predetermined plural number of field periods set as one cycle, fluctuations in pixel potentials stored in display pixels based on the display signal voltages applied via the signal lines are canceled in the predetermined plural number of field periods.
A drive control method of a display drive device according to a sixth aspect of the present invention for acquiring the above-stated advantage comprises: acquiring display data and holding the display data in parallel with one another; converting each predetermined number of the held display data, into pixel data in which the respective display data are arranged in a predetermined arranging order and in time-series; generating display signal voltages which correspond to the pixel data; and sequentially applying the display signal voltages corresponding to the pixel data to each the predetermined number of signal lines of a plurality of signal lines, in an order corresponding to the arranging order of the display data in the pixel data, in writing periods which are variedly set so as to correspond to writing speeds at display pixels.
The applying of the display signal voltages to each the predetermined number of signal lines sets the writing period for the signal line to which the display signal voltage is applied at a last timing among the predetermined number of signal lines, to a period which continues until writing of the display signal voltages in the display pixels is completed.
These objects and other objects and advantages of the present invention will become more apparent upon reading of the following detailed description and the accompanying drawings in which:
A display drive device according to the present invention, a drive control method of the same, and a display apparatus having the display drive device will be specifically explained by illustrating embodiments thereof.
First, the entire configuration of the display apparatus having the display drive device according to the present invention will be shown and then the display drive device and the drive control method of the same will be explained in detail. In the embodiments to be shown below, a case will be explained where the display drive device and display apparatus according to the present invention are applied to a liquid crystal display apparatus employing an active-matrix type drive system.
As shown in
According to the first embodiment, the source drive 130A and the gate driver 120A can be formed as driver chips which are independent from an insulating substrate such as a grass substrate on which is formed a pixel array including the plurality of two-dimensionally arranged display pixels Px constituting the liquid crystal display panel 110.
Each element of the above-described liquid crystal display apparatus will now be specifically described with reference to
As shown in
In the gate driver 120A having this configuration, when a gate start signal GSRT and a gate clock signal GPCK are supplied as vertical control signals from the LCD controller 150, the shift register 121 sequentially shifts the gate start signal GSRT based on the gate clock signal GPCK. The shift register 121 inputs the shifted signal to one input point of each of the plurality of AND circuits 122 which are provided correspondingly to the scanning lines SL.
In a state where the gate reset signal GRES is set to a high level (“1”) (driven state of the gate driver 120A), the other input point of the AND circuit 122 always receives a level “1”. As a result, the signal of the high level (“1”) is output from the AND circuit 122 at a timing at which the shifted signal is output from the shift register 121, based on the gate start signal GSRT and the gate clock signal GPCK. Scanning signals G1, G2, G3, . . . having a predetermined high level are generated through the level shifters 123 and 124 and the output amps 125, and sequentially applied to the scanning lines SL1, SL2, SL3, . . . . Thereby, the group of display pixels Px, which are connected in each row extending along each of the scanning lines SL1, SL2, SL3, . . . to which the scanning signals G1, G2, G3, . . . are applied, are simultaneously set to a selected state.
On the other hand, in a state where the gate reset signal GRES is set to a low level (“0”) (reset state of the gate driver 120A), the other input point of the AND circuit 122 always receives a level “0”. As a result, regardless of the presence/absence of an output of a shifted signal from the shift register 121, a signal having the low Level (“0”) is always output from the AND circuit 122, so that scanning signals G1, G2, G3, . . . having a predetermined low level are generated and the group of display pixels Px connected in each row extending along each of the scanning lines SL1, SL2, SL3, . . . are set to a non-selected state.
As shown in
The digital-analog converter 134 and the output amp 135 constitute the display signal voltage generation circuit according to the present invention.
As shown in
In
The signals to be supplied to the components described above are supplied from the LCD controller 150. The horizontal shift clock signal SCK, the horizontal period start signal STH, the control signal STB, the polarity control signal POL, and the output enable signal OE are horizontal control signals. The multiplexer control signals CNmx0 and CNmx1 and the switch reset signal SDRES are data conversion control signals.
The multiplexer control signal CNmx2 (switch toggling signals SD1 to SD3) supplied to the dividing multiplexer 136 may be one of horizontal control signals supplied from the LCD controller 150 as well as the above-described control signals. Or, a switch drive circuit (switch drive control circuit) 137 may be provided as shown in
In a case where the switch reset signal SDRES having a low level (L) is supplied from the LCD controller 150, the switch toggling signals SD1 to SD3 are set to a low level (L) regardless of the signal levels of the Multiplexer control signals CNmx0 and CNmx1, and supply of the display signal voltage to each data line DL is cut. In a case where the switch reset signal SDRES having a high level (H) is supplied from the LCD controller 150, any of the switch toggling signals SD1 to SD3 is set to a high level (H) based on the signal levels of the multiplexer control signals CNmx0 and CNmx1. And any of the transfer gates TG1 to TG3 to which the switch toggling signal SD1, SD2, or SD3 having a high level is applied is turned on, and the display signal voltage is supplied to the data line DL.
The switch drive circuit 137 may be provided in the source driver 130A or outside the source driver 130A. Further, as shown in a later-described second embodiment of the display apparatus (see
In
The source driver 130A having this configuration is parallely and sequentially supplied from the display signal generation circuit 160, with display data Rdata, Gdata, and Bdata corresponding to the display pixels Px in each row adapted to the colors RGB. After the display data Rdata, Gdata, and Bdata corresponding to one group of display pixels adapted to RGB colors are acquired, the display data Rdata, Gdata, and Bdata are converted into pixel data RGBdata comprising serial data in which each display data is arranged in time-series, based on the data conversion control signals. Then, a display signal voltage Vrgb, in which display signal voltages Vr, Vg, and Vb corresponding to the display data Rdata, Gdata, and Bdata in the pixel data RGBdata are arranged in time-series, is generated. Then, the display signal voltages Vr, Vg, and Vb are divided to the data lines DL1 to DL3, DL4 to DL6, . . . based on the data conversion control signals. As a result, for example, the display signal voltage Vr corresponding to the red component Rdata in the display data is supplied to the data lines DL1, DL4, DL7, . . . DL(k+1). The display signal voltage Vg corresponding to the green component Gdata is supplied to the data lines DL2, DL5, DL8, . . . DL(k+2). The display signal voltage Vb corresponding to the blue component Bdata is supplied to the data lines DL3, DL6, DL9, . . . DL(k+3). (k=0, 1, 2, 3, . . . )
The arranging order of the display data Rdata, Gdata, and Bdata in converting the display data Rdata, Gdata, and Bdata into the pixel data RGBdata, and the order of applying the display signal voltages Vr, Gg, and Vb to the data lines DL1 to DL3, DL4 to DL6, . . . are synchronously controlled by the data conversion control signals (multiplexer control signals CNmx0 and CNmx1 and switch reset signal SDRES). In this case, the order of applying the display signal voltages Vr, Gg, and Vb is controlled between the normal order of Vr-Vg-Vb and the reverse order of Vb-Vg-Vr.
The display signal generation circuit 160 extracts a horizontal synchronous signal, a vertical synchronous signal, and a composite synchronous signal from a video signal (composite vide signal or the like) supplied from the outside of the liquid crystal display apparatus 100A, and supplies the extracted signals to the LCD controller 150 as timing signals. At the same time, the display signal generation circuit 160 executes predetermined display signal generation processes (pedestal clamp, chroma process, etc.) to extract luminance signals (display data) of R, G, and B colors included in the video signal, and outputs the luminance signals to the source driver 130A as analog signals or digital signals.
The LCD controller 150 generates a horizontal control signal and a vertical control signal based on the horizontal synchronous signal and the vertical synchronous signal supplied from the display signal generation circuit 160, and various timing signals such as a system clock, etc., and supplies the generated signals to the gate driver 120A and the source driver 130A. The LCD controller 150 generates the data conversion control signals (multiplexer control signals CNmx0 and CNmx1 and switch reset signal SDRES) for controlling the operation states of the input multiplexers 133A and the dividing multiplexers 136, as a function unique to the present invention. The LCD controller 150 supplies the data conversion control signals to the source driver 130A (assume that the switch drive circuit 137 is included in the source driver 130A).
The drive control method of the liquid crystal display apparatus according to the first embodiment will now be explained with reference to the drawings.
(First Drive Control Method)
Here, the dividing multiplexer 136 has the configuration shown in
According to the drive control method of the liquid crystal display apparatus having the above-described configuration, with one horizontal period (1H) set as one cycle, the gate driver 120A applies a scanning signal Gi to a scanning line SLn on the n-th row and sets the group of display pixels Px on the row to a selected state, as shown in the timing chart of
During this selected period, at predetermined timings based on the data conversion control signals, the source driver 130A causes the input multiplexer 133 and the dividing multiplexer 136 to respectively execute conversion of display data into pixel data and dividing of the pixel data in synchronization with each other, for each group of three data lines DL1 to DL3, DL4 to DL6, . . . .
That is, as shown in the timing chart of
This writing operation is repeated during one field period (one vertical period; 1V), so that scanning signals G1, G2, G3, . . . are sequentially applied to the scanning lines SL1, SL2, SL3, . . . constituting the liquid crystal display panel 110 and display data for one screen of the liquid crystal display panel 110 are written on the display pixels Px. According to the present embodiment, the liquid crystal display panel 110 includes 320 scanning lines SL.
According to the first drive control method, the multiplexer control signals CNmx0 and CNmx1 are changed per each field period as shown in the timing chart of
On the other hand, in the (q+1)th field period which is an even ordinal number field period, with the group of display pixels Px in each row set to the selected state, the display signal voltages Vr, Vg, and Vb divided for the respective data lines DL1 to DL3, DL4 to DL6 . . . in each group are sequentially applied thereto in the order (reverse order) of Vb-Vg-Vr.
Thus, each display pixel Px is set to a gradational state corresponding to the applied display data and desired image information is displayed on the liquid crystal display panel 110.
A characteristic effect of the first drive control method will now be specifically described by employing a comparative example.
The timing chart shown in
As described above, the first drive control method is characterized by inverting the order of applying (supplying) the divided display signal voltages Vr, Vg, and Vb to the data lines (display pixels Px) between an odd ordinal number field period and an even ordinal number field period. As compared with this, according to the drive control method (hereinafter referred to as “comparative example”) shown in
As shown in
According to the drive control method of the comparative example, the order of applying the divided display signal voltages Vr, Vg, and Vb to the data lines (display pixels Px) is fixed. As shown in
The amount of charges leaked from each display pixel Px is dependent on the order of applying the display signal voltages Vr, Vg, and Vb to the display pixels Px (data lines DL) (or dependent on the time left in the selected period after writing operation). For example, as shown in
Therefore, according to the drive control method in which the order of applying the divided display signal voltages Vr, Vg, and Vb to the data lines DL (display pixels Px) is fixed, any adjacent data lines DL (any adjacent groups of display pixels Px arranged in the column direction) have a constant difference in their leak current amounts. Therefore, even in a case where the display signal voltages are set such that a display image (raster display) having no unevenness in the luminance will be displayed, a problem arises that as shown in
Hence, according to the first drive control method, as shown in
According to the liquid crystal display apparatus having the above-described configuration, the display signal voltages to be supplied to the display pixels Px connected to the data lines DL constituting the liquid crystal display panel 110 are converted in the source driver 130A, into time-division serial data for each data line group including a plurality of data lines DL. The display signal voltages corresponding to the plurality of data lines DL can be transmitted through a single signal line. The numbers of D/A converters 134 and output amps 135 provided in the source driver 130A and the number of signal lines connecting these elements to the transfer switch circuits (dividing multiplexers 136) can therefore be reduced to 1/given number (1/number of data lines included in each data line group). Accordingly, the circuit scale of the source driver 130A can be reduced and the chip size of the source driver 130A can be reduced. And because the power consumed by the D/A converters 134 and output amps 135 can be reduced, the power consumed by the source driver 130A can be reduced.
According to the first embodiment, display data supplied as parallel data in j lines (j is an arbitrary positive integer; 3 lines (j=3) in a case where the color components of RGB are concerned as described above) is converted by the multiplexer (input multiplexer 133) into serial data and transmitted to the transfer switch circuit. The dividing multiplexer 136 divides the serial data to the plurality (j number) of data lines DL. The source driver 130A having this configuration executes signal processes at j times as high an operation speed (at j times as large a clock frequency) as that of a conventional (well-known) source driver which simply acquires display data, converts it to display signal voltages, and outputs the voltages.
The display data to be processed by the source driver 130A (multiplexer 133 and dividing multiplexer 136) is not limited to data in three lines corresponding to the color components RGB in the above-described display data, but may be parallel data in 2 lines or 3 or more lines. In this case, multiplexers having a predetermined number of input or output terminals corresponding to the number of lines in the display data are employed.
(Second Drive Control Method)
The following explanation will be made by timely referring to the configuration of the above-described liquid crystal display apparatus (see
According to the above-described first drive control method, the multiplexer control signals CNmx0 and CNmx1 are changed per field period, so that the dividing operation of the dividing multiplexer 136 in the source driver 130A. i.e., the order of applying the display signal voltages Vr, Vg, and Vb is changed between field periods. According to the second drive control method, the multiplexer control signals CNmx0 and CNmx1 are changed per field period and per horizontal period (selected period).
That is, according to the first drive control method, the order of applying the display signal voltages Vr, Vg, and Vb is switched between the normal order of Vr-Vg-Vb and the reverse order of Vb-Vg-Vr per field period, as shown in
Hence according to the second drive control method, the above-described liquid crystal display apparatus changes the multiplexer control signals CNmx0 and CNmx1 per field period and also changes them per horizontal period (selected period). Further, the order of applying the display signal voltages Vr, Vg, and Vb, which are applied to the data lines DL by the dividing multiplexer 136 in the source driver 130A is switched between the normal order and the reverse order per field period likewise the above-described first drive control method (see
Due to this, the order of applying the divided display signal voltages Vr, Vg, and Vb to the data lines DL (display pixels Px) is switched at least per selected period (per horizontal period). Therefore, as compared with the first drive control method, changes in the luminance of the display image due to the differences in leak current amount between the data lines DL (groups of display pixels Px arranged in the column direction) occur at a shorter cycle. As a result, even in a case where a certain image such as a raster display or the like is displayed, flickers are less recognizable and the display quality can be improved.
(Third Drive Control Method)
The following explanation will be made by timely referring to the configuration of the above-described liquid crystal display apparatus (see
According to the above-described first and second drive control methods, unevenness in the luminance (deterioration of the display quality), which is due to a decrease in the pixel potential caused by leakage of charges written and stored in the display pixels Px in a selected period (horizontal period), is suppressed. According to the third drive control method, burn-in in the liquid crystal and deterioration of the display quality are suppressed by further taking into consideration the influence caused by a decrease in the pixel potential due to a field through voltage ΔV which is inherent in a liquid crystal display panel.
According to the first and second drive control methods, the dividing operation by the dividing multiplexer 136 is controlled such that the order of applying the display signal voltages Vr, Vg, and Vb is switched between the normal order of Vr-Vg-Vb and the reverse order of Vb-Vg-Vr at least per field period, as shown in
As well known, a field inverting drive method and a line inverting drive method are applied to a liquid crystal display panel in order to prevent burn-in caused by application of a direct-current voltage to the liquid crystal. Due to these methods, for example, as shown in
In this case, as explained in the first drive control method, charges stored in the display pixels Px are leaked via the protection element provided to the data line DLn in the remaining selected period after the writing operation is completed. Along with this, when the selected period ends (supply of the scanning signal Gm is cut; application of the scanning signal Gm of a low level is started), a voltage drop amounting to a well-known field through voltage ΔV occurs. Accordingly, a substantial pixel potential Vpix stored in a display pixel Px amounts to the difference between a voltage (pixel electrode voltage) VDnpx obtained by subtracting the field through voltage ΔV from the data line voltage VDn immediately before the selected period ends and the common voltage Vcom.
In an odd ordinal number field period in which the display signal voltage Vr (data line voltage VDn) set at a higher potential than the common voltage Vcom is applied, the data line voltage VDn decreases due to the leakage of charges after writing operation at the timing T. As shown in
Hence according to the third drive control method, as shown in
As shown in
The pixel electrode voltage VDnpx of a display pixel Px is determined based on the charges leaked in the remaining selected period after writing operation and a voltage drop caused by a field through when the selected period ends.
Hence according to the third drive control method, as shown in
In the (q+1)th field period (even ordinal number field period) and in the (q+2)th field period (odd ordinal number field period), the data line voltage VDn has almost no leakage of charges caused after writing operation at the timing T2 and timing T3. The pixel electrode voltage VDnpx of a display pixel Px decreases from the data line voltage VDn by the field through voltage ΔV, changing in a direction going away from the Vcom center (or the common voltage Vcom) or changing to a voltage still having a sufficient voltage difference from the Vcom center.
That is, as shown in
(Fourth Drive Control Method)
The following explanation will be made by timely referring to the configuration of the above-described liquid crystal display apparatus (see
In the above-described first to third drive control methods, a case has been explained where the operation of writing a display signal voltage, which is applied to a data line by the dividing multiplexer of the source driver, on a display pixel is completed within a predetermined writing period (that is, a case where the size of the pixel transistor provided in the display pixel is relatively large). As compared with this, according to the fourth drive control method, the writing period is varied in accordance with the time required for the operation of writing a display signal voltage, which time is dependent on the size of pixel transistor provided in the display pixel.
That is, for example, in a high-definition liquid crystal display panel or a compact liquid crystal display panel in which the area of each display pixel is small, the pixel transistor is formed in a small size so that the aperture ratio becomes large. In this case, the drive power of the pixel transistor becomes smaller and the time the pixel transistor takes to write the display signal voltage applied thereto from the source driver through the data line to the pixel capacitor becomes relatively long.
According to the above-described first to third drive control methods, the respective writing periods Tc which are set in a selected period are set to be equal and the time required for the operation of writing the display signal voltage to each display pixel is longer than the writing period Tc. In this case, in the display pixels Px to which the display signal voltages Vr and Vg are applied and whose pixel transistors are continuously turned on even after the set writing periods elapse because the selected period does not end at that time of elapse, the operation of writing the applied display signal voltages is completed before the selected period ends, as shown in
As compared with this, according to the fourth drive control method, in the liquid crystal display apparatus described above, the timing at which the input multiplexer 133 converts display data into pixel data and the timing at which the dividing multiplexer 136 divides the pixel data are controlled to be synchronous by the data conversion control signals. In this case, the data converting timing and the data dividing timing are controlled such that a writing period Tb, which is set at least in the last part of a selected period (1H) at the timing at which the display signal voltage Vb is applied, is set to continue until the operation of writing the display signal voltage Vb is completed, whereas the other writing periods Tr and Tg, which are set in the first and middle parts of the selected period, are set to be shorter than the writing period Tb, as shown in
According to this method, in the display pixels Px whose pixel transistors are continuously turned on even after the writing periods Tr and Tg elapse because of the still continuing selected period, the operation of writing the display signal voltages Vr and Vg is completed before the selected period ends. For the display pixel Px which has the selected period end generally at the same time the writing period Tb ends, the writing period Tb is set to a period which continues until the operation of writing the display signal voltage Vb is completed. Therefore, any of the display signal voltages can be written excellently. In other words, the writing amounts can be equalized. As a result, an excellent display quality can be obtained because the data line voltages VDn, VDn+1, and VDn+2 which are based on the display signal voltages Vr, Vg, and Vb correspond to the pixel potential Vpix.
In the fourth drive control method shown in
The second embodiment of the display apparatus according to the present invention to which the above-described drive control methods are applicable will be explained with reference to the drawings.
The elements which are the same as those in the first embodiment will be denoted by the same or similar reference numerals and explanation for such elements will be simplified or omitted.
As shown in
According to the second embodiment, such a configuration as shown in
The source driver 130B is formed as a driver chip independent from the insulating substrate SUB. The source driver 130B is electrically connected to the insulating substrate SUB via wiring electrodes (connection points) formed on the insulating substrate SUB, and is structured as an external (add-on) component of the insulating substrate SUB.
In this case, the pixel transistors (corresponding to the pixel transistors TFT shown in
The following explanation will be made by timely referring to the configurations shown in
As shown in
As shown in
The source driver 130B includes the same elements as those of the source driver 130A shown in
The transfer switch circuit 140 is roughly the same as the transfer switch section shown in
Accordingly, it is possible to improve the display quality and product life of the display apparatus according to the second embodiment by applying the above-described drive control methods for suitably suppressing occurrence of flickers due to leakage of charges stored in the display pixels, burn-in in the liquid crystal due to a biased pixel potential, writing defect due to the speed of writing in the display pixel (pixel transistor), etc.
In the display apparatus according to the second embodiment, the source driver 130B converts the display signal voltages to be supplied to the display pixels Px connected to the data lines DL provided on the liquid crystal display panel 110 (pixel array PXA), into time-division serial data for each data line group including a plurality of data lines DL. The source driver 130B outputs the time-division serial data to the transfer switch circuit 140 which is formed integrally with the pixel array PXA on the insulating substrate SUB. With this configuration, the time-division serial data for each data line group can be divided by the transfer switch circuit 140 at time division timings, and can be sequentially applied to the data lines DL in each data line group in a predetermined order. Therefore, the transfer switch circuit 140 provided on the insulating substrate SUB and the source drive 130B provided independently from the insulating substrate SUB can be connected by a number of connection terminals corresponding to the number of groups of data lines DL.
Accordingly, it is possible to reduce the number of connection terminals between the liquid crystal display panel 110 and the source driver 130B to 1/given number (1/number of data lines included in each data line group) and design the connection terminals with a relatively large pitch. As a result, the number of steps required for the connection process can be reduced and the liquid crystal display panel 110 and the source driver 130B can be suitably connected even with a relatively low connection precision, making it possible to reduce the production cost.
In the above-described embodiments, a case has been explained where the display apparatus according to the present invention is applied to a liquid crystal display apparatus. However, the present invention is not limited to this. The present invention can be applied not only to a liquid crystal display panel but also to other display panels such as an organic EL (electroluminescence) panel, etc. Further, in a case where the present invention is applied to a display panel conforming to an active-matrix type drive system, the gate driver and the switch drive circuit can be integrally formed. Therefore, a shared circuit configuration and a shared drive control method (processing of control signals, etc.) can be applied to the gate driver and switch drive circuit.
Various embodiments and chances may be made thereunto without departing from the broad spirit and scope of the invention. The above-described embodiments are intended to illustrate the present invention, not to limit the scope of the present invention. The scope of the present invention is shown by the attached claims rather than the embodiments. Various modifications made within the meaning of an equivalent of the claims of the invention and within the claims are to be regarded to be in the scope of the present invention.
This application is based on Japanese Patent Application No. 2003-435928 filed on Dec. 26, 2003 and including specification, claims, drawings and summary. The disclosure of the above Japanese Patent Application is incorporated herein by reference in its entirety.
Number | Date | Country | Kind |
---|---|---|---|
2003-435928 | Dec 2003 | JP | national |
The present application is a Divisional Application of U.S. application Ser. No. 11/023,116 filed Dec. 27, 2004 now U.S. Pat. No. 7,511,691, which is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2003-435928, filed Dec. 26, 2003, the entire contents of which are incorporated herein by reference.
Number | Name | Date | Kind |
---|---|---|---|
6980191 | Nakamura et al. | Dec 2005 | B2 |
7006072 | Ahn | Feb 2006 | B2 |
7030865 | Ishiyama | Apr 2006 | B2 |
7102606 | Miyajima et al. | Sep 2006 | B2 |
20030011581 | Tanaka et al. | Jan 2003 | A1 |
Number | Date | Country |
---|---|---|
1319833 | Oct 2001 | CN |
1389847 | Jan 2003 | CN |
1417771 | May 2003 | CN |
11-167373 | Jun 1999 | JP |
2003-058133 | Feb 2003 | JP |
2003-122313 | Apr 2003 | JP |
2003-140626 | May 2003 | JP |
2003-38332 | May 2003 | KR |
Number | Date | Country | |
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20090146939 A1 | Jun 2009 | US |
Number | Date | Country | |
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Parent | 11023116 | Dec 2004 | US |
Child | 12370361 | US |